Fram Forum 2019

FRAM CENTRE

Theme: Plastic Plastic in the Arctic Plastic in Arctic fish diets Developing biodegradable plastic PhD course in plastic Retrospective: Johan Hjort Profile: Dorte Herzke

Research Kongsfjorden sea ice observation Atlantification in Kongsfjorden Polar bear or “aquabear”? Salmon louse pesticide sampling Science in environmental policy A marine system in our backyard A new approach to governance Climate and cryosphere project Consequences of oil spills on fishes Polar cod in a changing Arctic Mineral particles in tailings Monitoring whales with drones Svalbard reindeer trends – 40 years

The Nansen Legacy Climate shift around Svalbard Where seals dare SEATRACK 2014-2018 Geological mapping in Antarctica In brief Bowheads, Narwhals, Quantarctica 3

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FRAM FORUM 2019

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CONTENTS

FRAM FORUM 2019

Publisher Framsenteret AS

CONTENTS 3 – Editorial 4 – Picture of the year 6 – Profile: A woman of action 12 – Kongsfjorden sea ice development observation 18 – Atlantification of the marine ecosystem in Kongsfjorden 24 – Polar bear or “aquabear”? 28 – Passive sampling detects salmon louse pesticides and H2S 32 – The scientific road towards international environmental policy 36 – Plastic in the Arctic: work in progress 38 – When plastic becomes part of Arctic fish diets 42 – Confronting a great challenge – plastic waste in nature 46 – Great interest for research on plastic waste 50 – A local fjord – investigating a marine system in our backyard 56 – To the future and back: Future governance of environmental risk 64 – Engaging users to improve future sea ice forecast services 68 – Assessing the consequences of oil spills on commercial fish 72 – Polar cod early life stages up against a changing Arctic 76 – Retrospective: Johan Hjort, a marine research pioneer 84 – Roundness of mineral particles in subsea tailings 88 – Monitoring whales with drones 92 – What can 40 years of reindeer monitoring data tell us? 98 – Extreme diversity in the songs of Spitsbergen’s bowhead whales 100 – The Nansen Legacy 106 – Warm water, fresh water, wind and tides – ice around Svalbard? 112 – Where seals dare 118 – Large-scale seabird movements – SEATRACK 2014-2018 122 – Arctic “unicorns” – year-round residents of western Fram Strait 124 – Two towers 128 – Geological mapping of Norway’s least explored mountains 132 – Quantarctica 3 released 134 – Historic photo: Two Sámi among penguins in the Antarctic 136 – Fram Centre Flagships 2018 143 – Contact information

FRAM Forum is published once a year on behalf of FRAM – the High North Research Centre for Climate and the Environment. Its aim is to inform the general public about the wide range of activities that take place within the Fram Centre. It is available free of charge to any and all who are interested in topics related to climate, environment, and people in the High North.

Editor Janet Holmén Freelance editor // alchemia@online.no Executive Helge M Markusson Outreach coordinator Fram Centre // helge.markusson@framsenteret.no Editorial committee Cathrine Henaug NINA Norwegian Institute for Nature Research // cathrine.henaug@nina.no Elin Vinje Jenssen Norwegian Polar Institute // elin.vinje.jenssen@npolar.no Eva Therese Jenssen University Centre in Svalbard // eva.therese.jenssen@unis.no Christine F Solbakken NILU – Norwegian Institute for Air Research // christine.solbakken@nilu.no Ellen Kathrine Bludd UiT The Arctic University of Norway // ellen.kathrine.bludd@uit.no Gunnar Sætra Institute of Marine Research // gunnar.saetra@imr.no Cover photo Ice thickness measurements being taken on thin sea ice in Kongsfjorden, Svalbard. Photo: Sebastian Gerland / Norwegian Polar Institute Layout TANK Design AS www.tank.no Printer Lundblad Media AS Online version www.framforum.com Contact information FRAM Forum Fram Centre POB 6606 Langnes, N-9296 Tromsø NORWAY www.framsenteret.no post@framsenteret.no Phone: +47-7775 0200

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EDITORIAL

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LIVING WITH UNPREDICTABILITY. IT’S COMPLICATED... Norwegian environmental management is expected to be knowledge-based. That means the agencies tasked with management need to understand the current state of the environment, factors that drive or influence natural processes, and possible ways to shape developments. It is sometimes argued that the High North is a simple system, easier to understand than a species-rich rain forest ecosystem or a densely populated area perturbed by human activities. Research carried out at the Fram Centre shows that this is a misconception: high-latitude systems are not simple at all. Many of the studies presented in this issue of Fram Forum expose contradictions, uncertainties and difficulties that must be resolved along the way to knowledge. The article about the Atlantification of an Arctic fjord (p 18) likens documentation of climate-related changes in a marine ecosystem to detective work. After years of painstaking “sleuthing” the researchers can discern some trends, but still can’t definitively predict which species will be the ecosystem’s winners and losers. Even members of a single species can be affected differently by climate change. Forty years of monitoring of Svalbard reindeer (p 92) show that warmer summers and milder winters may be detrimental to reindeer living on sparsely vegetated Brøggerhalvøya, but advantageous to those living on the lusher tundra in Adventdalen, just 125 km away. Several influential research organisations have recently released alarming reports showing that climate change will continue relentlessly, with unpredictable effects. The reports make it clear that time is short. We must take action immediately. But climate change is far beyond the reach of knowledge-based Norwegian management in isolation: tackling this problem requires international cooperation.

Policy-making is a crucial step in taking action, but the road to international environmental policy can be long and bumpy. The Minamata Convention on Mercury was decades in the works (p 32), even though mercury’s toxicity was acknowledged, its sources few, and the threats it posed both global and dire. The most important greenhouse gases are not toxic at their current atmospheric concentrations. They originate from countless sources and they spread all around the globe. But they don’t kill people outright: their threat is insidious, easy to ignore. How do we convey the urgency of this complex problem? The research into the Minamata process highlights five important factors if a nation is to succeed in international policy negotiations. The first of these is to have a sound scientific foundation and communicate this knowledge in such a way that non-experts can understand. The research environment at the Fram Centre is diverse and highly productive, as this issue shows. But to fully leverage our ability to establish a sound scientific foundation, we must release the synergies the newly expanded Fram Centre offers. This will benefit international processes as well as supporting knowledge-based management in the High North. As for communicating our knowledge in a comprehensible manner, we hope Fram Forum will do just that.

Janet Holmén, Editor

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PICTURE OF THE YEAR

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Kronebreen is calving Thunder rolls under the clear Arctic sky. Eagerly your eyes scan the face of the glacier. There! A chunk of blue ice the size of a railroad car tips with impossibly slow grandeur and plunges into the water. Waves churn towards you, threatening to swamp your boat. Watching a glacier calve is thrilling: beauty and peril combined. This is Kronebreen. When explorers first saw it in the late 1800s, it extended 10 km further into Kongsfjorden. By the end of WWII, the front had retreated about 6 km. From the late 1980s to about 2000, it lay another couple kilometres farther east over a rise in the seabed, which kept the glacier in a stable position. But ultimately the delicate balance between ice flow toward the front and ice loss through calving shifted and the front retreated into deeper water. With more water eating away at the base of the glacier, calving increased, and since 2011 the glacier front has retreated by over 2 km. Is this because of global warming? Clearly several factors are at play. Subglacial topography has nothing to do with climate. But Kronebreen’s mass balance is also affected by climate factors like the amount and type of precipitation, radiation, summertime melt, and water temperatures in Kongsfjorden. Those temperatures are influenced by the West Spitsbergen current, which has been warming for the past 40 years. So no, global warming isn’t the only explanation for the spectacular calving in eastern Kongsfjorden. But it clearly contributes. Photo: Geir Wing Gabrielsen / Norwegian Polar Institute

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PICTURE OF THE YEAR

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PROFILE

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All photos: Helge Markusson / Fram Centre

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PROFILE

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Christine Kristoffersen Hansen

A woman of action Environmental chemist Dorte Herzke has an urgent mission. If she always seems to be locked away in the lab it’s because that’s where the magic happens, where she and her team are trying to figure out how to save the world.

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verything is happening at breakneck speed. The environmental changes in just the past twenty or thirty years in the Arctic have been enormous.” Dorte Herzke taps the end of a blue ballpoint pen on her desk. “If we look at the number of chemicals produced, the quantities released into nature, what the poisons do to us and what they’re doing to the environment, it’s obvious this can’t continue for twenty or thirty more years.” The tapping on her desktop accelerates. “In other words, we’re in a hurry. A great hurry. But to figure out what we need to do to turn these developments around, we have to look at the big picture and understand how things fit together.” A BELIEVER IN APPLIED RESEARCH This focus on the big picture and her eagerness to find measures that actually work are recurring themes in Herzke’s career. When all the other students in her Chemistry class at the University of Berlin intended to go into basic research, Herzke decided to join the Institute for Water, Soil and Air Hygiene in West Berlin.

“I had no desire to disappear into a lab for three years and re-emerge with a chemical substance no one had heard of and no one had any use for. I’ve always considered applied research to be more important. That, and acquiring knowledge that can be used for something worthwhile.” Herzke completed a PhD in Analytical Chemistry in 1998. And what led her to Tromsø? She says it was a combination of coincidence and luck. “There aren’t many openings for analytical/environ­ mental chemists in Germany, so I both wanted to leave the country and had to. Right before I finished my PhD, I participated in a conference where I spoke with a guy who worked in the same field as me, but in Norway. I said he should keep me in mind if a job opportunity should crop up there,” says Herzke, adding: “And luckily he did!” The job offer landed on her desk a few months later: a six-month post-doctoral research position at NILU – Norwegian Institute for Air Research. Almost exactly twenty years after signing her temporary contract, Dorte Herzke is now a senior researcher and section leader at NILU’s Environmental Chemistry Department.

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PROFILE

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“The post-doctoral position became a two-year temporary job, and then I got a permanent position. Initially, I had no intention of staying here, but now I’m very happy that it turned out that way for us. I really like it here.” CHEMIST FATHER Herzke’s curiosity about chemistry, nature and the environment was piqued when she was still a child in Berlin. Her father should probably take a lot of credit for her career choice; he is also a chemist. “He never said, now we are going to talk about chemistry, but whenever we were hiking or exploring, he would draw our attention to things in nature and explain them to me and my big sister. And he always

answered all our questions. I remember one of those – which, incidentally, we would never have asked if we’d grown up in Tromsø: Why does the asphalt get soft when it’s hot?” Nonetheless, it was many years before Herzke decided to follow in her father’s footsteps. “I was rebellious and would rather do anything besides studying chemistry,” she laughs, and says she was toying with the idea of becoming a designer. “But my lack of creative talent put a stop to those plans relatively early, and eventually I got over my rebellious phase. Still, I did choose a different branch of chemistry than my father’s. I opted for environmental and analytical chemistry; he’s a process chemist.”

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PROFILE

FOLLOW THE RUBBER CRUMBS Herzke’s focus at NILU is environmental toxins in humans, animals, air, water and products. Among other things, she is responsible for a project that aims to find new pollutants in biological materials from Arctic regions. Herzke was also active in the European CleanSea Project, which is focused on plastic waste in the ocean. Over the past couple of years she has also dedicated a lot of time to the “Check your artificial soccer turf” campaign (Sjekk kunstgressbanen). Herzke and her colleagues recruited 12 000 schoolchildren to help find out what happens to the 3 000 tonnes of so-called crumb rubber granulate that disappears from artificial soccer turf in Norway each year. “The whole project was triggered by the fact that I walk past Gyllenborg School on my way to work every day. One day I saw two huge sacks of rubber granulate that would be used to replenish the artificial turf in the schoolyard. I also noticed the storm drain just a few metres away from the turf. A few days later, the entire schoolyard was black; it was obvious that a lot of those tiny balls of rubber would soon end up in the storm sewer. And where does the water from the storm drains in Tromsø go? Straight into the sea, of course!” According to Herzke, rubber granulate is often made from old car tyres. The researchers are now trying to find out what happens when these rubber granulate balls end up in the ocean. “We asked schoolchildren all over Norway to help us get the best possible overview of the extent of this pollution. I find it very rewarding working this way. It combines applied research with effective dissemination of knowledge.” In all her projects, Dorte Herzke is fascinated by the complexity and interactions in the environment. “What effects do environmental pollutants have where they are? How do they get there? And what do we need to do to make sure we don’t get even more of them? Everything is interconnected with everything else.”

CHALLENGES IN THE ARCTIC Most of the research done at NILU’s laboratory at the Fram Centre is f­ ocused on the Arctic. According to Herzke, this is both exciting and challenging, partly because the effects of pollution are especially notice­ able in this region. “There aren’t many big factories here, but we find a bunch of different pollutants here anyway – pollutants that come from other parts of the world. For example, look at the polar bear: it’s one of the world’s most poisoned animals. It’s astonishing that polar bears can have such high concentrations of pollutants in their bodies after eating nothing but seals and bird eggs – and never being anywhere near a factory. This is all our doing. Humans can choose what they eat; the polar bear can’t. All that poison in the polar bears – it’s our fault, not the bear’s.” Herzke says it is important to acknowledge how great a factor human activity is in the amount of pollution in the Arctic.

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DARK START

“We continue to pollute the world, and this will have consequences for the health of our children and for the animals that live around us. We know a great deal about the effects of our actions, but we choose not to act accordingly. Sometimes it seems as if we are doing more of what shouldn’t do, not less of it. “So what should we do?” asks Herzke, then answers her own question. “We need to live simpler lives. And we need to be smarter about how we use things, how products are manufactured, how we recycle and how we re-use the things we buy. We need to learn that nothing we throw away is ever gone.” Herzke fears that in only twenty or thirty years, the air in nearly all the world’s metropolises will be as bad as it is now in Beijing and Mumbai. She is also afraid even more people will lack access to clean drinking water and that our food will be full of harmful chemicals. “If there’s one thing I hope to achieve as a researcher, it would be to figure out how we can live simpler lives and reverse this trend. Of course, much responsibility lies with politicians, but each and every one of us will have to do what we can. We can’t just sit and wait for someone else to decide how we should do things. It doesn’t work that way.”

Herzke’s office is located on the third floor of Fram II, the Fram Centre’s new wing on the south side of the complex. People who work in these offices can expect visitors to drop by around noon on the first clear day after 15 January. In Tromsø, that’s when the sun peers over the southern horizon for the first time since late November, and those in south-facing offices have front-row seats. But today the sky is pitch black and a daylight lamp next to Dorte’s computer monitor is standing in for the sun. Despite having lived in Tromsø for two decades, she is still not a fan of the dark period. Some of her aversion might come from her first encounter with northern Norway. “Before I got the job in Tromsø I had only been in Norway once, on a summer holiday in Valdres. When my husband and I loaded our car and left Berlin we didn’t really know what we had ahead of us.” They decided to drive through Sweden and Finland and approach Norway via Kilpis. “This was in early February. The temperature was 30 degrees below zero. And long stretches of that road are also extremely dark and deserted; only forest, forest, forest as far as the eye can see.” This was before GPS, so they used a good old-fashioned map to find their way. But driving through Lavangsdalen and realising that they should only have a few dozen kilometres to go before reaching Tromsø, they began to wonder if they were on the right road. “I admit I wondered a bit what we’d got ourselves into. The nights kept getting longer and darker, and the closer we got to our destination, the fewer people we saw. We were both relieved when we finally rounded the last curve and suddenly saw light and civilisation.”

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PROFILE

Needless to say, the couple were welcomed with open arms and ultimately made themselves a new home here. But when Herzke thinks back on her first year in Tromsø, it is almost exclusively her work she ­remembers.

“I realised you have to love being outdoors if you want to thrive here. We made sure we learned to love it over time, though we’re not yet as accustomed to going out as Norwegians. We go skiing, but we go slowly. And we go alone.”

“It was a hectic period. I was very keen to find out about everything I would be doing and how to do it. There was a lot to learn, and I also had to learn a new language. I have vague recollections that it was horrible summer – it rained constantly – and that a huge amount of snow fell the following winter. But I didn’t give it much thought. It wasn’t until a year had gone by that I started exploring my surroundings. When I could finally breathe a little deeper, I began to enjoy nature and explore the city.”

Outdoor excursions are great for thinking deep and thinking big. For Herzke, this may mean pondering new projects she might start at NILU.

HIKES AND DEEP THOUGHTS In addition to her exciting job, credit for keeping Herzke and her husband in Tromsø goes to the mountains, ski slopes and forests. They try to get out as often as they can with their two teenage daughters.

“My interests seem to change all the time. Fortunately, I am in a position where I more or less create my own working situations. Since our work is based mostly on projects – and one of my responsibilities is precisely to create new projects – I tend to come up with suggestions that align with my interests. Of course, nobody funds my projects just because I think they would be fun to do. We have to apply for funding many times – and occasionally we get a green light. “But no matter what I do, it’s important not to get too engrossed in a single topic. Everything is interconnected. We must never lose sight of that.”

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RESEARCH NOTES

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Sebastian Gerland, Dmitry Divine, Jean Negrel and Olga Pavlova // Norwegian Polar Institute Torbjørn Eltoft // UiT The Arctic University of Norway Nick Hughes // MET Norwegian Ice Service Rune Storvold // Norut Northern Research Institute Janne Søreide // The University Centre in Svalbard

Kongsfjorden sea ice development observed from ground, air and space Sea ice covers parts of fjords in Svalbard for a limited time during winter and spring. The ice plays important roles for climate processes, such as heat and radiation fluxes between atmosphere and fjord water, and for the fjord’s ecosystem. Through the years, many studies have focused on Kongsfjorden.

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RESEARCH NOTES

Snow thickness measurements are important since snow affects the surface energy balance of the sea ice. It is relevant for the ecosystem, as it determines how much light reaches the water under the sea ice. Snow is also important for ringed seals, which give birth to their pups in snow dens on the ice. Photo: Jean Negrel / Norwegian Polar Institute

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CryoWing Scout drone and the Radionor communication equipment that allows for real-time data transfer of both visual and thermal imagery of the ice and real-time analysis of sea ice fraction and ice floe sizes. Photo: Rune Storvold / Norut Northern Research Institute

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hile kongsfjorden is a site of long-term monitoring of sea ice by the Norwegian Polar Institute, add-on studies are performed to study specific process and to improve fjord ice observations. The objective of the project “Mapping Sea Ice” is to establish more efficient methods for retrieval of important fjord ice parameters from remote sensing data. This will provide accurate information on sea ice – both current status and future changes – thus informing work in climate and ecosystem science. Here we give an overview on this project, and related results from the Norwegian Polar Institute’s long-term sea ice monitoring in Kongsfjorden, and from the CIRFA Centre for research-based innovation, led by UiT The Arctic University of Norway. SEA ICE MONITORING IN KONGSFJORDEN Systematic long-term fast-ice monitoring for inner Kongsfjorden started at the Norwegian Polar Institute in 2003; it includes mapping of sea ice extent and in situ sea ice measurements at several sites in the fjord. Sea ice extent maps are drawn by hand based on

visual assessments and photographs of the fjord surface from the top of Zeppelinfjellet (474 m a.s.l.) near Ny-Ålesund. Ice and snow thickness and freeboard are measured in and next to drill holes. Data on ice extent and thickness are needed for quantitative estimates of sea ice mass balance, and to determine long-term trends and interannual variability. In addition to the pure monitoring of thickness and extent, other physical and chemical properties are observed when conditions allow, and when specific process studies can be added onto the monitoring. This also includes validation and calibration of satellite remote sensing. SATELLITE OBSERVATION OF COASTAL SEA ICE Satellite-based remote sensing techniques offer an important alternative to ground observations thanks to high temporal resolution and consistency of the data. Optical data are relatively cost-effective and easy to process, but depend on daylight and clear sky conditions. Radar sensors such as synthetic aperture radar (SAR) have the advantages of being independent of daylight and clouds, and they can offer richer

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Maximum fast-ice coverage area (km2) in Kongsfjorden east of Ny-Ålesund for each month from February to June in the period of 2003-2017. (Modified from Pavlova et al. 2019)

information about ice conditions, but processing is more complex. Typical satellite products used for climatology studies are based on low resolution passive microwave sensors, which cannot resolve the details in coastal zones. Ice charts for Svalbard have been based on medium resolution optical satellite data since the early 1980s, and on high-resolution SAR for the past ten years. We are currently working on improving automated extraction of sea ice parameters to provide better support for climatology studies and ice chart validation. Work includes methods to extract information on fast ice from optical data, and classify sea ice types from SAR products. Features such as ice edge positions observed in situ are compared with those detected using SAR products, showing both possibilities and limitations of ice edge mapping.

UNMANNED AIRBORNE SYSTEMS Unmanned airborne systems (UAS) have been used over Kongsfjorden and surrounding areas regularly during the past decade. Advantages of such systems compared with manned aircraft are lower costs, and less environmental impact. However, UAS still require an experienced team on site, and the payloads are substantially smaller than for manned systems. The Hamnerabben airport at Ny-Ålesund has a specific facility for UAS. The aircraft currently in use is a Cryo­ Wing Scout, which superseded the CryoWing Roamer a few years ago. The Scout carries a camera and an inertial navigation system. While earlier flight tracks were pre-programmed, the system has recently been refined so that flight tracks can be adjusted in real time. This can be extremely useful. For example, automated decision-making based on the images obtained now allows us to follow the ice edge. In the 2018 field season, the UAS payload was further extended with an infrared camera to ease discrimination between open water and thin ice.

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SEA ICE IS DECLINING Sea ice is home to tiny organisms, seen here as a

Systematic observations of sea ice extent during the period 2003-2017, plus preliminary results from 2018, reveal that the inner part of Kongsfjorden is usually covered by seasonal fast ice. This ice forms sometime between December and March and persists until April-June. Before 2006, the sea ice typically extended into the central part of the fjord, but during the last decade the sea ice has often been restricted to the inner northern part. Most years after 2006 had low ice extent and a short fast ice season. Based on in situ measurements of ice and snow thickness, and freeboard since 1997, we have found that the thickness of both fast ice and snow has declined over the observation period, towards thinner ice and snow cover. During the first years of the monitoring, fast ice was about 0.7 m thick at its seasonal peak. In recent years, except for 2011 and 2018, the peak thickness has been around 0.2 m. In parallel, snow thickness decreased from around 0.2 m to less than 0.05 m. However, the interannual variation in ice extent and ice and snow thickness appears to be substantial. Advection of Atlantic water into Kongsfjorden in combination with relatively mild winters are likely the main factors underlying changing fast-ice conditions in Kongsfjorden. Sea ice monitoring in Kongsfjorden is not only used for climate change research: it also contributes to past, ongoing and future process studies in many disciplines, conducted in the research village of NyÅlesund. The combination of in situ, airborne and satellite observations done in this project gave promising results. Follow-up work within “Mapping Sea Ice” and other related projects will aim at (i) standardising and implementing routine use of remote sensing combined with in situ observations and sampling, and (ii) applying interdisciplinary approaches in other locations such as Storfjorden, another Svalbard fjord where sea ice monitoring is carried out. Thus, our understanding of the interconnected physical and biological processes will be improved, and the connections between changing coastal sea ice conditions and ecosystem processes in Svalbard will be better quantified.

brown layer of millions of microscopic ice algae at the bottom of a chunk of ice pulled from the water. Since 2018, sea ice physicists and biologists in the “Mapping Sea Ice” project have been working together to study this poorly known sea ice habitat which may be essential not only for the tiny organisms at the base of the Arctic food web, but also for ringed seals and polar bears. Photo: Malin Daase / UiT The Arctic University of Norway

ACKNOWLEDGEMENTS We thank personnel from the Norwegian Polar Institute in NyÅlesund for help with monitoring and technical support during fieldwork. The projects “Mapping Sea Ice”, “ARCEx” and “CIRFA SFI” are funded by the Fram Centre Fjord and Coast Flagship, and by the Research Council of Norway, along with the participants’ home institutes. The project “RESICE” is funded by the Norwegian Ministry of Foreign Affairs (programme Arktis 2030). The long-term monitoring of Kongsfjorden sea ice is funded by the Norwegian Polar Institute.

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FURTHER READING: Negrel J, Gerland S, Doulgeris AP, Lauknes TR, Rouyet L (2018) On the potential of hand-held GPS tracking of fjord ice features for remote-sensing validation. Annals of Glaciology 59 (76pt2): 173-180, https://doi.org/10.1017/aog.2017.35 Pavlova O, Gerland S, Hop H (2019) Changes in sea-ice extent and thickness in Kongsfjorden, Svalbard (2003-2016). In: Hop H, Wiencke C (eds.): The ecosystem of Kongsfjorden, Svalbard. Advances in Polar Ecology, Springer Verlag. Publication date 27 April 2019

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Mikko Vihtakari1, Haakon Hop2, Philipp Assmy, Gary Griffith, Pedro Duarte, Anette Wold and Geir Wing Gabrielsen // Norwegian Polar Institute Malin Daase, Bodil Bluhm and Else Nøst Hegseth // UiT The Arctic University of Norway Paul E Renaud3 // Akvaplan-niva Janne E Søreide // University Centre in Svalbard Børge Moe // Norwegian Institute for Nature Research

Atlantification of the marine ecosystem in Kongsfjorden, Svalbard Climate warming is rapidly altering the physical marine environment in fjords on the west coast of Svalbard towards a more temperate state. Reductions in sea ice cover and increased ocean temperatures are evident, resulting in changes of ­­ ice-associated and pelagic ecosystems.

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ocumenting climate-related changes in a marine ecosystem is detective work. Oceans are in a constant state of change due to weather, currents, tides, and seasonality. Consequently, samples collected from the same spot even just a few minutes apart can vary considerably. Similar to judges in a court, scientists need reliable evidence to ascertain that differences among samples taken over time are part of a long-term trend rather than shorter-term natural variability. Acquiring such evidence requires thoughtful long-term sampling campaigns and thorough statistical analysis of collected data. During the last years, researchers working in Kongsfjorden have published long-term ecological and physical data series. These time series range from diet samples collected from seabirds to direct measurements of temperature, sea ice and plankton abundances. Shifts in the ecosystem

Also affiliated with the Institute of Marine Research Also affiliated with UiT The Arctic University of Norway 3 Also affiliated with the University Centre in Svalbard 1 2

reflecting physical changes are now apparent and sometimes surprising. Phytoplankton investigations in Kongsfjorden date back to the early 1970s with systematic monitoring each summer since 2009. The time series indicates three different spring bloom scenarios. Until the early 2000s, Kongsfjorden often had a long-lasting ice cover, and the phytoplankton bloom was in May. The recent decrease in sea ice cover has resulted in an earlier bloom in April. Both these bloom scenarios are characterised by the dominance of diatoms due to weak thermal gradients allowing resting spores to be mixed up into the water column during winter. The last scenario, encountered during the warmest years in the time series, is associated with a surface inflow of Atlantic Water during winter, preventing deep win-

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Inner Kongsfjorden in 1922 and 2002. The glacier cover has declined dramatically with implications for the marine ecosystem in the fjord. Photos: Anders Orvin and Christian Åslund

ter mixing and ice formation. This scenario results in a delayed and diminished bloom dominated by colonies of Phaeocystis pouchetti. Such changes in the timing, magnitude, and composition of the spring bloom can have ripple effects on the entire marine food web. Zooplankton has been monitored each summer in Kongsfjorden since 1996. The time series shows an increase in the contribution of the Atlantic copepod Calanus finmarchicus, possibly due to warming and loss of sea ice in Kongsfjorden. Surprisingly, the abundance of its Arctic cousin C. glacialis has not declined in Kongsfjorden nor in Isfjorden further south. Earlier onset of the spring bloom, combined with warmer temperatures does not appear to displace C. glacialis but rather to improve its breeding efficiency, shorten its life cycle and reduce its body size to resemble the

smaller C. finmarchicus. The transfer of energy, from primary producers through Calanus to higher predators, may then become more efficient due to changes in generation length and population turnover rate that accompany the changes in body size. For size-selective predators, however, smaller copepods will be harder to catch than larger ones, and as the efforts increase, the rewards decrease. Diet samples collected from black-legged kittiwakes – surface-feeding seabirds – indicate that the pelagic ecosystem in Kongsfjorden abruptly changed in 2007, becoming more Atlantic. Polar cod, a High Arctic fish, and the pelagic amphipod Themisto libellula, an Arctic crustacean, dominated the kittiwakes’ diet until 2006. Following a large inflow of Atlantic water to the fjord during the winter of 2006, capelin, a pelagic fish

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adapted to warmer North Atlantic waters, became an important part of the birds’ diet. After the change in 2007, the contribution of polar cod in kittiwake diet did not return to the previous levels. Instead, the diet contained a more varied range of species including Atlantic herring, which appeared in the diet samples in 2012 coinciding with another Atlantic inflow event. Further, there was more polar cod in kittiwake diet during years with more sea ice, and conversely, more Atlantic fishes during years with less sea ice and higher water temperatures. This indicates that increasing ocean temperatures and decreasing sea ice concentration might indeed have caused the increased occurrences of Atlantic fishes and crustaceans in kittiwake diet samples. The change in diet has not affected the breeding success of kittiwakes in Kongsfjorden, and the population trend has been slightly positive since 2007. Ecosystem changes have also occurred in the nearshore zone at the seafloor. A 30-year photographic time series of rocky bottom subtidal benthic communities shows an increase in macroalgal cover from the mid-1990s in Kongsfjorden, and in Smeerenburgfjorden further north. Given that algae provide new habitat, several benthic invertebrates also became more abundant, while others declined. These shifts in

the benthic community were associated with climatic changes, specifically ice decline and warming water, reflecting increased prominence of Atlantic water conditions. However, the species structure of the community of muddy bottom-dwellers has not responded consistently to warming; rather, we observe changes over time that could be related to variability in other physical drivers. The long-term ecological research from Kongsfjorden has been used to investigate how the changing environmental conditions are altering the ability of the marine food web to absorb, recover and adapt to the Atlantification. An important aspect of this work has focused on ecological resilience, which is the ability of the Kongsfjorden marine food web to continue to withstand further changes. The results show that the Atlantification event in 2006 resulted in a significant loss of ecological resilience, with the system becoming more susceptible to a loss of biodiversity. However, since 2013, changes in how species feed and interact with each other show an improvement in ecological resilience. The secondary productivity has also increased both in Kongsfjorden and in coastal areas of Svalbard. While further observations are required, this provides preliminary evidence of a new emergent marine food web adapting to climate change.

Black-legged kittiwakes fighting over a capelin in Kongsfjorden. Photo: Guttorm Christiansen / Akvaplan-niva

5 oE

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Panel a) Svalbard with Atlantic and Arctic currents influencing Kongsfjorden. Panel b) Records of sea ice index (blue) and ocean temperature (red) in Kongsfjorden. Lower sea ice index implies less sea ice. Temperature data are from Tverberg et al. (2019) The Kongsfjorden Transect: seasonal and inter-annual variability in hydrography, which will appear in “The Ecosystem of Kongsfjorden, Svalbard”. The figure is modified from Vihtakari et al. (2018).

The marine ecosystems on the west coast of Svalbard are influenced by the northwards flowing West Spitsbergen Current, a branch of the warm North Atlantic Current, making the fjords respond to climate change earlier than fjords situated elsewhere in the Arctic. The “Atlantification” signal is penetrating deeper into the fjords along the west coast than previously because of increased temperature in the West Spitsbergen Current.

This change influences the base of food webs, with phytoplankton converting energy from the sun during the spring bloom into sugars and lipids that are grazed by herbivorous zooplankton such as the Calanus copepods. Atlantic predators such as Atlantic cod may also change the ecosystem by increased predation pressure on smaller fishes such as polar cod and lower trophic levels.

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Kittiwake diet item

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80 60

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81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 00 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16

Year

Polar cod, Atlantic fish species, mostly Atlantic krill, and Arctic Themisto occurrence in black-legged kittiwake diet during summers from 1982 to 2016 in Kongsfjorden. Numbers above the blue bars indicate the number of diet samples analysed per year. Modified from Vihtakari et al. (2018)

The changes we observe in Svalbard are happening fast: the fauna in the west coast fjords is now less characteristic of the High Arctic, but more and more resembles the ecosystems along the Norwegian coast, with food webs partly composed of Atlantic species. This analogy indicates that Arctic species remaining in the ecosystem may gradually decline in abundance and eventually disappear altogether. The change, however, does not appear to have reduced the productivity of the system but has rather led to increasing secondary productivity. Further, some Arctic species such as C. glacialis appear to be able to adjust to the new regime by adopting life history strategies similar to those of Atlantic species, thus making the ecosystems resilient to the change. The jury is still waiting for more evidence on the outcome of competitive interactions between the Atlantic newcomers and the Arctic residents before proclaiming the losers and winners of the grand scale climate experiment.

FURTHER READING: Renaud PE, Daase M, Banas NS, Gabrielsen TM, Søreide JE, Varpe Ø, Cottier F, Falk-Petersen S, Halsband C, Vogedes D, Heggland K, Berge J (2018) Pelagic food-webs in a changing Arctic: a trait-based perspective suggests a mode of resilience. ICES Journal of Marine Science 75:1871-1881. doi, 10.1093/icesjms/fsy063 Vihtakari M, Welcker J, Moe B, Chastel O, Tartu S, Hop H, Bech C, Descamps S, Gabrielsen GW (2018) Black-legged kittiwakes as messengers of Atlantification in the Arctic. Scientific Reports 8:1178. doi, 10.1038/s41598-017-19118-8 Several articles about this work will appear in the book “The Ecosystem of Kongsfjorden, Svalbard” (eds. Hop H, Wiencke C), Advances in Polar Ecology, Springer Verlag, publication date 27 April 2019.

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?

a)

? b)

?

c)

?

d)

e)

f)

g)

h)

i)

Marine organisms and how they may respond to Atlantification in Kongsfjorden. Arrows indicate whether Atlantification is expected to have a positive or negative effect. Question marks indicate uncertainty. a) diatoms; b) the colony-forming haptophyte Phaeocystis pouchetii; c) the Atlantic copepod Calanus finmarchicus; d) the Arctic pelagic amphipod Themisto libellula; e) the krill Thysanoessa inermis; f) polar cod Boreogadus saida; g) Atlantic cod Gadus morhua; h) capelin Mallotus villosus; i) Atlantic herring Clupea harengus Photos: Philipp Assmy (a,b), Malin Daase (c-e), Peter Leopold (f), Marcus Boyne (g), Jan de Lange (h,i)

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Polar bear swimming in the pack ice north of Svalbard in August 2015. Photo: Magnus Andersen / Norwegian Polar Institute

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Jon Aars, Karen Lone, Christian Lydersen, Magnus Andersen and Kit M Kovacs //Norwegian Polar Institute

Polar bear or “aquabear”? Ursus maritimus – the polar bear’s Latin name clearly identifies it as a marine animal, not a terrestrial one. Recent studies show they deserve this name: not only do they live much of their lives near sea ice; they also spend more time in water, swim farther and dive deeper than was thought previously.

I

n 2008, scientists from the united states deployed a subcutaneous temperature logger, in combination with a telemetry collar, on a female polar bear in the Beaufort Sea. Geographic position, internal temperature and ambient temperature were measured simultaneously, making it possible to figure out when the bear was swimming and when she was walking on sea ice. This bear swam continuously for more than nine days, travelling 687 km. These data proved that polar bears are able to swim for much longer distances than previously thought. HOW FAR DO POLAR BEARS SWIM? In recent years, satellite collars deployed on polar bears have become more sophisticated and many now record time spent in the water, using a salt water switch (two contact points that carry current between them when in salt water). For Svalbard bears, we have documented several cases where bears have swum more than 100 km (280 km at most) and been in the water continuously for up to four days.

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An old male polar bear diving in the pack ice north

Female with a newly deployed satellite collar, with her

of Svalbard in August 2015.

yearling daughter. The collar records activity (proportion

Photo: Jon Aars / Norwegian Polar Institute

of time with recorded movement within 2-hour periods, at 1-second resolution), percentage of time in water, and temperature. Photo: Jon Aars / Norwegian Polar Institute

Such long swims in the Barents Region are always trips between islands in the region’s archipelagos and the sea ice edge, where most bears hunt much of the year. Pregnant females increasingly often face long swims in the autumn to return from the ice to the islands to make their maternity dens in drifts of snow on land, where they give birth to their cubs in midwinter. This situation is rather new. A few decades ago, sea ice covered much of the ocean surrounding Svalbard for most of the year and corridors of sea ice were virtually always available between the islands and ice-covered hunting areas. Back then, bears rarely had to swim long distances.

Mothers with small cubs swim much less than other females, particularly in early spring. Tiny cubs are unable to survive long periods in icy water, as they lack the fat layer that insulates larger, older bears when swimming. (Their fur insulates well in air, but not when it is wet.) Thus, when they first emerge from the birth den, bear families are quite vulnerable in habitats with many open leads in the ice, and in areas with little sea ice. It is important for the mother to get to good hunting areas quickly in the spring to regain weight so she can continue producing milk for the cubs, after a long winter in the den without eating. DIVING

TIME IN WATER Long swims are interesting in and of themselves, but it is also important to know about swimming behaviour on a daily basis, how it varies with season, habitat and other factors. A recent study from Svalbard (see further reading) showed that most female polar bears are very aquatic. How much time the bears spent swimming varied a lot through the year, but in July, they spent two hours a day in the water, on average. Individual bears also vary considerably in how much time they spend in the water.

We know that polar bears dive between and underneath ice floes when they hunt seals. Bears approach seals by stealth, swimming underwater so they are not detected. From time to time, they surface to check where they are in relation to the seal. Finally, when close enough, they do a final dive and emerge just in front of the seal’s resting place, and lunge onto the ice in an attempt to catch the prey. Polar bears also dive to find kelp and other things they like to eat, such

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This graph shows a female polar bear’s activity,

Track from the same bear’s GPS satellite collar. The

­temperature and percent of time in water before, during

straight lines show swimming. In June 2018 (for which sea

and shortly after she crossed more than 400 km of open

ice distribution is shown) she swam more than 400 km dur-

water. Note that her activity level drops as she swims,

ing more than a week to get from eastern Svalbard to Franz

and that the water is cold (<0°C).

Josef Land, stopping to rest for 20 hours on some sea ice.

as submerged carcasses. Our study from Svalbard revealed that adult female polar bears occasionally dived down to several metres depth. The record dive in the study was 13.9 metres!

equals the cost of a two-week long walk. If the mother has to swim a long distance to reach an island in autumn, it reduces her ability to produce milk for her cubs.

COST OF SWIMMING

It is also important to note that young bears will not be able to swim long distances at all – they lose too much heat. Therefore, even though adult bears are good swimmers and divers, having to make more long swims due to sea ice loss is a serious threat to this remarkable species.

Given the loss of sea ice in the Arctic in recent decades, it is good news that polar bears are able to swim long distances. In the Barents Region, including Svalbard, sea ice losses have been large, and predictions suggest that reductions will continue much faster here than in other areas inhabited by polar bears. Thus, we believe that bears in the area will need to swim even more in the future. Good denning areas in eastern Svalbard have already been lost. In years without sea ice in the autumn, pregnant females do not get to these areas any longer. The energetic costs of long swims may be too high. Pregnant females need sufficient fat reserves to ensure milk production, usually for two cubs, during a threeto-four-month period in the den without any access to food. The estimated cost of swimming is equivalent to 4 kg of fat per day! That is approximately five times the cost incurred by walking; thus a three-day swim

FURTHER READING: Lone K, Kovacs K, Lydersen C, Fedak M, Andersen M, Lovell P, Aars J (2018) Aquatic behaviour of polar bears (Ursus maritimus) in an increasingly ice-free Arctic. Scientific Reports 8, 9677

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Pernilla Carlsson, Åse Åtland and Øyvind Garmo // Norwegian Institute for Water Research (NIVA) Gro Harlaug Refseth // Akvaplan-niva

Passive sampling detects salmon louse pesticides and hydrogen sulphide: 50 shades of grey If you want to get Norwegians talking, just ask for their opinions on aquaculture. Use of pesticides to combat salmon lice in fish farms is a hotly debated topic all around Norway. But how much pesticide is actually spread in the environment? To find out, we’ve developed a new measurement strategy.

W

e wanted a tool to sample pesticides in the environment that was less dependent on timing, and able to detect very low concentrations in water around fish farms. This is highly relevant, as there is an ongoing debate concerning how far from a fish farm low – but potentially harmful – concentrations can be found after a discharge of delousing agents. THE PHYSICAL CHEMISTRY BEHIND OUR IDEA Our first task was to choose a sampling method. An active sampler works like a big vacuum cleaner and sucks a suitable amount of water over a sampling medium. A passive sampler is deployed in the waters being monitored and the target compounds

­ ccumulate in it over time. After exposure, the sama plers are retrieved and analysed. The concentration of a given compound in water can be estimated from the amount that has accumulated in the sampler, provided that factors controlling the uptake rate are understood. We chose passive sampling – a technique frequently used for measuring water contaminants at low concentrations in the environment. While active sampling has to be done when the plume of salmon louse pesticides passes the sampling point, a passive sampler can be deployed at strategic places before delousing, and be collected a few days later when the plume of pesticides has passed.

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Concentration of azamethiphos (ng/L) in sea water after delousing 100 80 60 40 20 0

Increasing distance from pen and primary direction of current

Treated pen

Concentrations measured in the deloused pen and at increasing distances down-current. The stars mark sampling points. One sampler was damaged and could not be analysed.

FIELD EXPERIMENT To test whether this method could detect salmon pesticides in the water after a delousing event, we deployed several polar organic chemical integrative samplers (POCIS) on the water surface at increasing distances away from a pen that would be deloused with azamethiphos the following day. Two days after delousing, the samplers were collected and sent to the NIVA laboratory for analysis. The graph shows how the amount of azamethiphos measured inside the pen (to the right in the background photo) is in accordance with the concentration applied during the delousing event (about 100

ng/L in the pen). Outside the pen, the concentration decreases with increasing distance. It is worth noting that this was a pilot project and we were not able to cover all possible current directions. Only one pen was deloused, which means that the amount of azamethi­phos used was lower than if all pens had been deloused at the same time, which is normally the case. Nevertheless, the technique proved its feasibility: passive sampling can be used to measure low pesticide concentrations in background areas as well as after delousing events. Our next step is to do field experiments on a larger scale.

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5(0) shades of grey – a laboratory test with samplers exposed to different concentrations of H2S, from 340 µg/L (left) down to 24 µg/L (right).

50 SHADES OF GREY IN A LABORATORY

RISK ASSESSMENT

Passive sampling can also be used for other compounds and in other contexts. One example is a pilot project we did together with aquaculture companies to find a method for detecting hydrogen sulphide (H2S) at low concentrations in recirculating aquaculture systems. H2S is chronically toxic for fish at 20 µg/L and can cause sudden death among fish in recirculating systems. Hence, the companies needed a quick and easy method for measuring H2S.

Recent studies on delousing agents have demonstrated that short term exposure to low concentrations of chemicals used for bath treatments can have effects on deep-water shrimps. Oceanographic modelling results vary depending on the chemicals being modelled, but suggest that relevant concentrations can be found up to 3 km away from a fish farm after delousing. Hence, there is a high demand for field studies on delousing agents to validate model results. The development of the passive sampling methodology for measuring delousing agents is important for overall assessment of the risk posed by delousing agents to the surrounding environment. We hope to continue this work, deploying more passive samplers at several depths, and using oceanographic models to better understand how azamethiphos spreads in the water.

Again, passive sampling is the solution! Samplers can be deployed and left for a suitable number of days while H2S accumulates in a binding layer containing silver iodide, which reacts with H2S. The reaction product is grey silver sulphide. The intensity of the grey colour can be measured and quantified by image analysis, and since the shade of grey depends on how much H2S accumulated in the sampler a certain shade of grey equals a certain concentration! As for salmon louse pesticides, increased exposure time gives more time for accumulation of the target compound which then can be measured and a water concentration can be calculated based on uptake rates. If a sampler deployed in a recirculating aquaculture system has taken on a pale but visible shade of grey within 48 hours, H2S is present in the water at about 5 µg/L.

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Salmon louse pesticides AZAMETHIPHOS: Organic phosphorous compound for bath treatment, effective on adult and mobile sea lice. Other crustaceans are sensitive to azamethiphos. CYPER- AND DELTAMETHRIN: Pyrethroids for bath treatment. They are less water-soluble than azamethi­ phos and their mode of action is on the nervous system of the sea lice and insects. EMAMECTIN BENZOATE AND DIBENZURON: Provided via fish feed. They act by inhibiting chitin synthesis and are fairly stable in water and sediments compared to other sea louse pesticides. HYDROGEN PEROXIDE (H2O2): A very strong oxidation agent. It is mainly efficient on mobile sea lice. Crustacean plankton are sensitive to H2O2. SOURCE: Sæther K, Refseth GH, Bahr G, Sagerup K (2016) Kunnskapsstatus lusemidler og miljøpåvirkning. Akvaplan-niva Report no. 8136-1, available at https:// www.fhf.no/media/155790/kunnskapsstatus_folder_269781_..pdf

We thank Fram Centre Incentive Funds 2017 and our collaborators Ole B Samuelsen and Ann-Lisbeth Agnalt (Institute of Marine Research), Ole Anders Nøst (Akvaplanniva), Thomas Rundberget, Bert van Bavel and Ian Allan (NIVA) and Even Jørgensen (UiT The Arctic University of Norway) for the azamethiphos work (ToolSalmon). The H2S project was funded by Hardingsmolt, Marine Harvest and NIVA.

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Perch is the national monitoring species for mercury in fish in Norway. Photo: Guttorm Christensen / Akvaplan-niva

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Trude Borch // Akvaplan-niva Froukje Maria Platjouw* and Eirik H Steindal // Norwegian Institute for Water Research (NIVA)

The scientific road towards international environmental policy Many environmental problems are global in character and must be resolved through joint international efforts. Examples include climate change, long-range transported environmental pollutants and plastic. Sound environmental policy-making to address transboundary pollution needs scientific backing.

T

he road from science to policy-making is often winding and it can take time from scientific findings on an environmental problem to the implementation of environmental policy. One important success factor in this process is making scientific findings accessible and understandable to actors outside the science community. SCIENCE AND INTERNATIONAL POLICY-MAKING Over the last four decades, nations have negotiated hundreds of bilateral and multilateral agreements to address transnational environmental problems. The role that nations play in such negotiations differs with national economic, political and scientific resources. Scientists in every country mainly share scientific resources with other scientists by publishing their

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Studying mercury in freshwater fish. Fieldwork at Jarfjordfjellet, Sør-Varanger, Norway. Photo: Guttorm Christensen / Akvaplan-niva

findings in peer-reviewed journals. But recent years have seen an increased focus on the need for popular dissemination and public outreach, and on the importance of providing advice to policy-makers. Large-scale international scientific assessments have also become a more common way of informing ­policy-making. Global environmental assessments (GEAs) are formal efforts to assemble selected know­ ledge to make it useful for decision-making. This objective highlights the importance of organising such assessments in ways that make it easy to identify products, participants, responsible authorities and the effects of an environmental problem on ecosystems and human health. GEAs mainly focus only on summarising and ensuring the quality of existing research, but they may also involve conducting new research. The national actors in the production and utilisation of GEAs in negotiation processes often include government agencies, private corporations, research institutions and NGOs. THE MINAMATA CONVENTION The World Health Organization lists mercury among the top ten chemicals or groups of chemicals of public health concern, and we have recently studied the process towards a global legally binding instrument on mercury: the 2013 Minamata Convention.

Despite many years of scientific consensus on the toxic effects and long-range transportation of mercury, it took a long time to establish a global, legally binding convention to regulate the contaminant. The first initiative towards international action on the mercury problem came in 2003, but it took six more years before the Governing Council of the United Nations Environment Programme (UNEP) agreed to start developing a legally binding approach (in 2009). MERCURY IN THE ARCTIC Due to its geography, climate and ecology, the Arctic is strongly impacted by the adverse effects of mercury pollution. As a result, research showing negative effects on human health and the environment in the Arctic was a key driver behind the initiative to set up the Minamata Convention. In our project on the Convention, led by NIVA and financed by the Fram Centre, we have analysed the science–policy interface on the road towards the adoption of the Minamata Convention, and the positions and roles of Norway and Canada in the Minamata process. The project concludes that the Arctic Council played an important role as knowledge provider in the process leading up to the Minamata Convention. In a recent publication we describe how this was particularly true of a working group within the Arctic Council – the Arctic Monitoring and Assessment Programme – which was heavily involved as a “science broker”, providing

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scientific assessments to back political decision-making in the negotiations. Both the Arctic Council and the Nordic Council also played important roles in research financing.

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­ witzerland, proposed to start negotiating an agreeS ment at the UNEP Governing Council meeting in 2003. Later, in 2009, Canada changed its view when the US changed its position on a legally binding agreement at the start of the Obama administration.

CANADA AND NORWAY Our project also examined the positions and roles of Canada and Norway in the scientific production, preparations, and alliance building in the UNEP negotiations, as well as their main arguments. The data for this study were collected through literature review and interviews with the leaders and delegates from the two countries. The delegations included representatives from government agencies and research institutes; the Canadian delegation also included an indigenous NGO. We found that both countries provided essential contributions to the realisation of the convention, though in different ways and at different phases of the process. Whereas Canada and Norway are both receivers of long-range transported mercury pollution from other countries, their respective pollution history differs. Being an industrial country with a population of 37 million and a large mining industry, Canada has substantially higher national emissions and releases of mercury than Norway (with a population of approximately 5 million). Like other countries with an economically significant mining industry, Canada was in a bit of a bind. The Canadian government wished to reduce national emissions, but also wanted to avoid putting overly strict regulations on their mining industry. Nonetheless, Canada made significant reductions in mercury emissions during the 1990s, as did Norway. As a substantial part of the mercury deposited in these countries originates from sources outside their respective boundaries, they both realised that further substantial reductions could only be achieved through international regulations.

Both Norwegian and Canadian input was central in the scientific research revealing that mercury travelled long distances from its original sources and into the Arctic. In Canada, mercury studies in the Arctic were led by the government’s Northern Contaminants Program. This programme also helped fund and build the capacity of an Arctic indigenous organisation, the Inuit Circumpolar Council (ICC). As a result, ICC was able to put efforts into mercury and help inform the negotiation process. It is clear from statements made by the Canadian Government that its principal concern in the negotiations was to protect the indigenous population and biota in the Arctic from mercury pollution. The environment and human health in the Arctic were also major concerns for Norway; however, the national stance on the convention was also motivated by scientific findings of high levels of mercury in freshwater fish of high food value in other parts of the country. From our study we conclude that the following are important for a nation to succeed in an international environmental policy process: 1) having a sound scientific foundation and communicating this in ways that non-experts can understand; 2) including experts among the delegates in negotiations; 3) having well-prepared position documents; 4) having strong national backing from government, industry and NGOs; and 5) having a negotiation team with the will and skill to compromise and build alliances.

FURTHER READING: However, Canada (along with Australia, the US, Japan and Russia) was initially against a legally binding agreement on mercury and argued for a voluntary solution. The main reason for opposition to such an agreement was concern about yet another resource-demanding negotiation procedure on chemicals. Norway, on the other hand, was in favour of a legally binding agreement and, together with

Platjouw F, Steindal EH, Borch T (2018) From arctic science to international law: the road towards the Minamata Convention and the role of the Arctic Council. Arctic Review on Law and Politics 9: 226-243

The project was financed by the Fram Centre Flagship “Hazardous substances – effects on ecosystems and human health” .

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France Collard, Ingeborg Hallanger and Geir W Gabrielsen // Norwegian Polar Institute Jakob Strand and Lis Bach // Aarhus University Kerstin Magnusson, Maria Granberg and Lisa Winberg von Friesen // IVL-Swedish Environmental Research Institute

Plastic in the Arctic: work in progress Although the first plastic material was created in 1907, scientists were not concerned about plastic pollution until the 1960s. Around 2010, concern grew to alarm. Now the scientific interest in how plastic affects the environment is rising – and the Arctic is no exception.

A trash pile collected on Svalbard beaches analysed during the Deep Dive workshop in Longyearbyen. Photo: France Collard / Norwegian Polar Institute

Y

ou might think the Arctic is remote enough to be safe from pollution. But we now know that plastic waste is a widespread challenge even in this region. For example, Arctic sea ice may be an accumulation zone for microplastics – small fragments of plastic – especially the smallest bits under 1 mm. The Norwegian Polar Institute is joining forces with national and international partners to gain knowledge about this issue. Several collaborations have already been established and more are expected thanks to the new Fram Centre Flagship “Plastic in the Arctic”. The unexpected findings in Arctic sea ice highlight the urgency of studying small microplastics. A new non-invasive method of sampling and extraction of microplastics from the stomach contents of birds is currently being tested at the Fram Centre. Birds are

Ongoing projects focus on plastic pollution in the Arctic from several perspectives: • benthic food chains around Svalbard and Greenland (PlastArc1) • uptake and effects of microplastics in arctic amphipods – an experimental study (PlastArc2) • sediment in Kongsfjorden • stomachs of fulmar chicks in the Faroe Islands PlastArc1 and 2 are being performed in collaboration with IVL-Swedish Environmental Research Institute and Aarhus University.

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given water to make them regurgitate, and microplastics down to 20 µm are extracted. This provides valuable data on interactions between plastics and biota.

Photo: Maria Granberg / IVL-Swedish Environmental Research Institute

From left to right, Norwegian Polar Institute scientists Lisa Orme, France Collard and ­Ingeborg Hallanger on board RV Lance. Photo: Arto Miettinen / Norwegian Polar Institute

Through these projects, we hope to raise awareness of stakeholders, companies and society and inspire them to work on solutions to reduce plastic pollution.

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Amalie Ask (University of Stavanger) collecting sand in Ny-Ålesund.

One big issue in the Arctic is the lack of wastewater treatment plants. In most places, untreated waste­ water is discharged directly into the environment. However, in Ny-Ålesund, a treatment plant has now been installed and scientists from IVL-Swedish Environmental Research Institute, Aarhus University and the Norwegian Polar Institute are currently investigating contents of anthropogenic microlitter in waste­ water itself, in Kongsfjorden outside Ny-Ålesund, and in other parts of the Arctic. Alongside its scientific research, the Norwegian Polar Institute has also been involved in a workshop organised by Wageningen Economic Research and SALT, a consultancy firm focused on coastal issues. The Deep Dive workshop sorted, weighed and analysed plastics collected from beaches in Svalbard. Each year, tonnes of plastic litter are collected from Svalbard beaches thanks to a collaboration between scientists, cruise operators, tourists and the Governor of Svalbard.

IN BRIEF

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Ellen Kathrine Bludd // UiT The Arctic University of Norway

When plastic becomes part of Arctic fish diets As consumers, we constantly hear that we should cut down our use of plastic packaging and choose textiles made from natural materials, free from plastics. But does it really matter so much? A fresh study from the Arctic Ocean provides gloomy evidence of why it matters.

P

lastics have many advantages in our daily lives, for instance they help us prevent food from going to waste, save energy in our homes and decrease CO2 emissions. According to Plastics Europe, global production of plastics has consistently increased and is currently at 335 million tonnes per year. However, plastic pollution is an emerging and growing threat across world oceans. Once plastics get out into the environment, they tend to break down into smaller debris also known as microplastics. Researchers from UiT The Arctic University of Norway investigated the presence of microplastics in the water and in two Arctic fish species off the coast of northeastern Greenland. MOTIVATED BY TRASH “What motivated us to investigate microplastics in Greenland is that we saw plenty of plastic debris when we went there in previous years to study Arctic fish communities,” says professor Jørgen Schou Christiansen from UiT.

Christiansen and colleagues have travelled regularly to Northeast Greenland since 2002 in connection with the TUNU Programme, a broad research effort to learn more about fishes and other marine fauna in the Arctic. Northeast Greenland has barely been studied, so the TUNU expeditions provide important baseline data. The researchers sampled water to study microplastics in the water column. They also wanted to see if fish ingested microplastics. The researchers picked out fish species with two different feeding strategies: the polar cod (Boreogadus saida) which feeds in open water or in areas where there is sea ice, and the bigeye sculpin (Triglops nybelini) which feeds on or near the bottom of the ocean. The polar cod is associated with sea ice that also stores a lot of microplastics, so the species could be particularly exposed to microplastics pollution.

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Researchers from UiT The Arctic University of Norway visited the waters northeast of Greenland with RV Helmer Hanssen to sample water and fish species and test for microplastics. Photo: Arve Lynghammar / UiT The Arctic University of Norway

Christiansen and his colleagues found plastic debris in their water samples at a concentration of 2.4 items/ m3 Âą0.8 SD, which is higher than in most seas at lower latitudes.

The most common microplastic the researchers found in the water column was polyethylene. It is the most abundant polymer type, and belongs to the largest product group of plastics. Polyethylene is widely used as packaging material and is often discarded after a single use.

Both fish species had in fact eaten microplastics. The researchers found that 34% of the bigeye sculpins contained microplastics, while 18% of the polar cod contained microplastics.

Polyester was the plastic most frequently found in fishes. Polyester is commonly used in textiles and fishing gear and has already been documented in both water and ice in the Arctic Ocean.

PLASTIC IN WATER AND FISHES

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During previous TUNU expeditions, researchers found floating plastic debris northeast of Greenland. Photo: Peter Rask Møller / Natural History Museum of Denmark

Examples of microplastics isolated from water samples using spectroscopy. A) white PVC fragment B) degraded polyethylene fragment C) grey/blue polyethylene fragment D) transparent polyamide fragment. Scale bars = 1 mm From Morgana et al. 2018, Environmental Pollution 242: 1078-1086. Used with permission.

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BLUE FOOD

MORE ACTIVITY IN THE ARCTIC

The difference between the species is most likely a result of feeding habits and the habitat in which they live. Microplastics seem to accumulate at the bottom of the ocean, where the bigeye sculpin feeds. As we all know, it’s not such a good idea to eat food from the floor!

The findings of the recently published study underscore that the Arctic is turning into a hotspot for plastic pollution, and this calls urgently for precautionary measures. Even though the Arctic currently does not have a lot of human activity, ocean currents bring in plastic litter from areas where humans have had greater impact.

The dominant colour of the microplastics found in fishes was blue, similar to the colour of the zooplankton they eat. It appears likely that they mistake the plastic material for their prey. Microplastics can also be consumed indirectly, by eating prey contaminated with the plastic. The fish species that prey on zooplankton and contain micro­ plastics can be eaten by top predators. This makes them carriers of plastics within the food chain. A major problem with microplastics is that they are small enough to be ingested by a wide range of organisms. This can create a false sense of feeling full. If the organisms then stop eating, they could miss out on nutrients that they need to survive. Ingested plastic may also injure the organisms or clog their digestive systems. Floating plastic debris could potentially also carry non-native bacteria, algae and even small animals that might threaten the biodiversity of environments they are transported to.

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In addition, sea ice is known to be a sink for micro­ plastic accumulation. As global warming continues to contribute to melting sea ice, the amount of plastic in the waters of the Arctic Ocean is likely to increase. With the reduction in sea ice, the Arctic is also expected to see more human activity, such as tourism, shipping, and fisheries. We expect this to further exacerbate microplastic pollution in the Arctic Ocean.

FURTHER READING: Morgana S, Ghigliotti L, Estevez-Calvar N, Stifanese R, Wieckzorek A, Doyle T, Christiansen JS, Faimali M, Garaventa F (2018) Microplastics in the Arctic: A case study with subsurface water and fish samples off Northeast Greenland. Environmental Pollution 242: 1078-1086, http://doi. org/10.1016/j.envpol.2018.08.001

FACTS ABOUT MICROPLASTICS Microplastics (MPs) are synthetic organic polymer particles less than 5 mm in size that may differ in shape, colour, and chemical composition. They can be categorised as primary or secondary. Primary MPs are used in specific personal care products (hand cleaners, facial cleaners and toothpaste). Secondary MPs come from larger pieces of plastic that gradually break down. About 75-90% of the plastic debris in the marine environment has been estimated to originate from land-based sources and 10-25% come from ocean-based sources.

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Vibeke Os // UiT The Arctic University of Norway

Confronting one of our greatest challenges – plastic waste in nature The oceans are filling with plastic. The water in some great Asian rivers is no longer visible below the flowing mass of trash. A rare Cuvier’s beaked whale stranded off the coast of Hordaland with its stomach full of plastic. Plastic waste is a formidable problem – with an unexpected possible solution.

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ur saviours may be some little rascals with undeservedly bad reputation – bacteria! It isn’t that they break down plastic waste. Rather, they can produce plastic: eco-friendly, biodegradable plastic. PLASTIC AS A CARBON STORE Bacteria are everywhere around us and inside us. It turns out that something akin to plastic serves as an energy reserve for many bacteria. Instead of storing fat for times when food is scarce as people do, bacteria store energy as polyhydroxyalkanoate (PHA), a polymeric compound with properties similar to those of plastic. The PHA polymer is considered the carbon store of bacteria. This biodegradable polymer is stored in large depots inside the bacteria, and scientists around the world are now showing great interest in bacteria that produce “plastic”.

“Lots of bacteria can produce PHA,” explains researcher Hilde Hansen from the Department of Chemistry at UiT The Arctic University of Norway. She is the leader of the MarPlast project, funded through the European Research Area networks initiative (ERANET). She and her research colleague Bjørn Altermark are looking for the best “plastic-producer” among the bacteria in the Arctic marine environment. Their search has led them to fish farms and fish processing plants in Troms County. HOPING TO UTILISE FISHY WASTE “In the last few years we’ve been looking for bacteria that are good at producing this plastic and that can be fed easily accessible raw materials,” says Hansen. “We want to utilise excess raw materials that already exist in large quantities that are readily available for

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Maybe if products were made of bacterially produced plastic, they would decompose instead of floating around in nature forevermore. Photo: Colourbox

large-scale production. We think it’s a very good idea, exploiting leftovers from the fishing and fish farming industries.” The researchers have visited fishing villages and fish farms, looking for bacteria that survive and thrive on what the fish farm industries leave behind. They have peered into nooks and crannies on boats, at docks, warehouses, fish processing plants, fish farms, and among seaweed and kelp. They take their samples back to the laboratory at the Siva Innovation Centre where scientists test which nutrients the bacteria need in order to grow and produce and store PHA. THREATS CAN BE MOTIVATING The idea of creating biodegradable plastic is not new. Scientists have known since the 1950s that bacteria

produce tiny balls of some kind of plastic. The first attempts to exploit these polymers were made in the 1970s, but proved too costly to use on an industrial scale. “And it’s still an expensive process,” Altermark points out. He explains that this type of research has been on hold for many years, but that the worldwide threat now posed by plastic pollution is increasing the amount of research funding available, and prompting the industry to renewed efforts to produce biodegradable plastics.

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Different bacteria produce different PHAs: they use different building blocks and the composition of the PHA is controlled by an enzyme inside the bacteria, which is called polymerase. In addition to searching for the perfect bacterium, Hansen and Altermark also study various polymerases, since the enzyme is the motor for plastic production inside the bacteria. The researchers want to design an enzyme that is more efficient than the others, a super-enzyme created to produce plastics with unique properties.

Up to 80-90% of the nutrition stored in bacteria can be “plastic”. This electron microscopic image shows the PHA-producing bacterium Ralstonia eutropha. The white fields are the bacteria’s PHA stores. The American company Danimer Scientific is making plastic bottles and straws from PHA. Photo: Department of Chemistry, UiT The Arctic University of Norway

PACKAGING, STRAWS AND PLASTIC BOTTLES Plastic produced by bacteria could be used for packaging and shopping bags, and could also be mixed with other components to modify the products’ properties and the time they take to decompose. According to the researchers, these new biodegradable plastics can take anywhere from months to years to break down, but they also emphasise that the plastic doesn’t disintegrate by itself. It needs to be introduced into an environment where there are microorganisms that can break it down.

Hilde Hansen and research fellow Mikkel Christensen examine a Petri dish in the lab. Bacteria are seeded onto Petri dishes and different growth conditions are tested. This is how the researchers search for b ­ acterial strains that tolerate salt, thrive on the nutrients available from fish waste, and can

“It is just like paper towels in your kitchen. They will last for years unless you put them in a compost heap. There, they will decompose fairly quickly.”

be grown in the laboratory. Photo: Vibeke Os / UiT The Arctic University of Norway

LONG CHAINS PHA molecules are built up in a way that allows microorganisms to chew them to pieces. There are several hundred varieties of PHA. One thing they all have in common is that they consist of a number of repeating building blocks which are linked together in long chains.

“If we learn more about the enzyme, maybe we can create plastics with exactly the properties we want,” says Altermark with a smile. “Then we can choose to make it brittle, rigid, strong or elastic. Just as an example, some surgical suture threads used at hospitals today are made of elastic plastic that decomposes on its own.”

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Approximately 300 bacteria have been screened for their plastic-producing capabilities. One of the methods used is to grow the bacteria in culture medium with dye added. Bacterial strains that glow pink under UV light (right plate) are probably plastic producers. Photo: UiT The Arctic University of Norway

TESTED MORE THAN 300 BACTERIA The two researchers can dream, but a lot of hard work remains to be done. So far, they have tested about 300 bacteria together with project partners in Bucharest and Umeå. Each bacterial strain is cultured in bottles or Petri dishes and examined using microscopy, spectroscopy and chromatography. They have found 15-20 promising strains of bacteria so far, including halophilic (salt-loving) bacteria of the Halomonadaceae family. These bacteria thrive well in environments with a lot of salt. Hansen says the challenge is to find the best conditions for PHA production. What makes a bacterium start storing carbon? We know that the relationship between carbon and nitrogen is important, so we want to find conditions that allow the bacteria to thrive and grow as much as possible. We need to look at such things as nutrition, salt concentrations and temperatures. She sums it up this way: “Under certain conditions, 80-90% of the cytoplasm can be PHA. That’s where we want to be.”

Hydroxybutyrate

Hydroxy- R= 50 different building blocks valerate

Polyester (PET)

R

Bioplastic-polymer (Polyhydroxyalkanoate)

An ordinary “fossil” plastic

Biodegradable polyhydroxyalkanoate (left) and conventional polyester (right) are similar in structure. The “R” group in the PHA molecule represents a wide range of chemical substituents that can give the polymer different characteristics. Ordinary plastic is highly resistant to breakdown by microorganisms.

FURTHER READING: Marplast: http://site.uit.no/marplast/ Article in Norwegian: Biodegradable fishing nets: https://forskning.no/ hav-og-fiske-marin-teknologi/lager-selvopplosendefiskegarn/426325

Researchers Hilde Hansen and Bjørn Altermark at UiT The Arctic University of Norway are searching the coast of northern Norway for bacteria that can feed on marine sources such as fish scraps from fish farming or the fishing industry. Photo: UiT The Arctic University of Norway

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EDUCATION

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Three of the students researching plastics are (left to right) Svenja Neumann, Ingunn Solheim Johnsen and Unni Mette Nordang. Standing behind them are supervisors Geir Wing Gabrielsen of the Norwegian Polar Institute, and Dorte Herzke of NILU – Norwegian Institute for Air Research. Photo: Helge M Markusson / Fram Centre

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EDUCATION

Helge Markusson // Fram Centre

Great interest for research on plastic waste There has never been more interest in researching the effect plastic pollution has on the High North. The institutions of the Fram Centre in Tromsø are experiencing a rush of students wanting to pursue a degree in the field.

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e could have admitted even more, that’s how great the interest is. But the great influx of qualified and enthusiastic students makes for better researchers in the long term.” This is according to Dorte Herzke, senior researcher and section leader at the Environmental Chemistry Department at NILU – the Norwegian Institute for Air Research. Five students are currently working towards Master’s degrees in the field of microplastics at the Fram Centre, in cooperation with NILU, the Norwegian Polar Institute, the Institute of Marine Research, UiT The Arctic University of Norway, and Ghent University (the Netherlands). Students with supervisors from Fram Centre member institutions have previously done research on plastic: since 2014, the Centre has welcomed students from Norway, Ireland, Iceland, Great Britain, the United States and the Netherlands.

“But we’ve never before had so many at the same time, and so many affiliated with the research environ­ment at UiT,” says Herzke. NEW LABORATORIES The growing number of students is a concrete result of the expansion of the Fram Centre’s building in Tromsø. In June 2018, the researchers in Tromsø could start using three brand new laboratories situated in the new building. One of these is NILU’s environmental pollution laboratory. “Yes, it has meant a lot. We now have room for more students and can pay more attention to them. And there’s a new clean room that allows us to carry out research we couldn’t do before. This gives the Fram Centre a competitive advantage,” says Herzke.

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Stine Benjaminsen collecting plastic waste in Svalbard. Photo: Adrian Kjellin

In addition, the expansion of the Fram Centre building has given Akvaplan-niva more lab space, which also allows them to compete for new assignments.

University of Norway and finished her Bachelor’s degree in pollution biology last year. She is now studying for a Master’s in marine ecology and resource biology, and is very concerned about the effect of plastic on the environment.

NEW RESEARCH PROGRAMME Two of the student positions are financed through two Fram Centre research programmes, and more positions are likely to open up later this year when the new research programme “Plastic in the Arctic” is launched. “This is plastic collected on beaches in Svalbard,” says Unni Mette Nordang. She gestures towards a few test tubes containing tiny pieces of plastic of different colours. “Now I’m going to test it for potential environmental pollution,” she explains. Nordang’s Master’s studies are supported through a partnership between NILU and UiT. Stine Benjaminsen chimes in. “I’ve been pestering them for a year, and finally I’m here,” she says. Benjaminsen is associated with UiT The Arctic

“I more or less grew up by the seaside, so I’m really worried about what’s happening. There’s a lot we still don’t know about plastic pollution,” says Benjaminsen. INTERNATIONAL ATTENTION The opportunities to study and do research, and the academic environment at the Fram Centre, have drawn international attention. Svenja Neuman from Germany, who is normally a student at Ghent University, is now a visiting student at the Norwegian Polar Institute, with Geir Wing Gabrielsen as supervisor. “I came here via Oslo and Svalbard, and I’ve settled in really well,” says Neuman. Gabrielsen, who also teaches at the University Centre in Svalbard and UiT, nods at this familar story.

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“I notice a huge amount of interest among students, both nationally and internationally. There’s a great lack of knowledge when it comes to plastic pollution, which means it’s crucial to educate bright students who can contribute to research, management and enterprise in years to come,” says Gabrielsen, who is head of the environmental pollution section at the Norwegian Polar Institute. TO CHINA Shortly before this issue of Fram Forum went to press, four students and four researchers/supervisors travelled to Shanghai in China to collaborate with Chinese researchers and students on the topic of plastic pollution. The trip, financed by the Research Council of Norway through the project PlastPoll, is a concrete result of the Fram Centre collaboration.

Unni Mette Nordang prepares to examine some plastic samples. Photo: Helge M Markusson / Fram Centre

EDUCATION

“There are great challenges associated with education, monitoring and research on plastics. In China, our students will have an opportunity to meet Chinese students and teachers working on plastic pollution. This visit will give us a chance to share our experiences of methods used to sample and study plastic, as well as studying the effects of plastic pollution. The visit to Shanghai will be useful for all of us and initiate closer collaboration with China on this vital problem area,” says Geir Wing Gabrielsen. Project Manager Herzke adds: “It’s important that the students go where the plastic is produced, and where pollution is a major problem. By strengthening the cooperation between Norway and China – two countries with vastly different challenges associated with plastic pollution – we can learn a lot from each other, including how to find solutions to this problem in the future.”

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Angelika HH Renner and Jofrid Skarðhamar // Institute of Marine Research Kathy Dunlop // Akvaplan-niva Ingrid Wiedmann and Evert Mul // UiT The Arctic University of Norway

A tale of a local fjord – investigating a marine system in our backyard

Winter in Kaldfjorden. Photo: Angelika Renner / Institute of Marine Research

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A cold wind gust hits our small aluminum boat, and we crash into another rolling wave. Spray splashes up but, for once, the cold, salty drops are welcome. Everyone in the fieldwork team is sweaty and breathless but very much alive. That was a close call, but we made it!

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The movement of three whales in Kaldfjorden between 27 and 29 November 2014, in ­relation to the estimated herring biomass, and shipping and fishing activities during the same days. Whale movement was reconstructed based on GPS instruments that were mounted with suction cups on the whales. The herring biomass is estimated based on echo sounder surveys.

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oday’s team was Angelika Renner, Zoe ­Walker, Ingrid Wiedmann, and Martin Biuw. We were out in Kaldfjord this morning to recover a short-term sediment trap array that consists of a surface buoy, a 130 m long rope and a 20 kg anchor at the bottom. Cylindrical tubes are attached to the rope at different depths; they collect the material that sinks out of the water above over a 24-hour period. But then, while we were hauling in the trap array, the winch broke. Dragging up almost 50 kg of equipment on a thin slippery rope is challenging and quickly turned into a strength training session. Even our boat’s helmsman Martin had to join in, but in the end the equipment and samples were on deck. Clear ­conclusion: next time we need a better winch and, just in case, more muscle power onboard!

WHY WERE FOUR SCIENTISTS OUT IN KALDFJORD, STRUGGLING IN THE WINTER WEATHER? It all started in winter 2010/2011 when herring suddenly entered the local ecosystem in Kaldfjord for the first time in years. So much herring, in fact, that their presence affected the entire ecosystem – changing the chemical composition of the water and attracting hundreds of humpback, killer and fin whales, as well as a large fishing fleet. Based on echo-sounder surveys conducted in the Fram Centre project weShare, we estimated the total herring biomass in the winter 2014/2015 to be 1 500 000 tonnes. This means that about 25% of that season’s total Norwegian spring spawning herring stock was present in Kaldfjord. weShare data also suggest that the 400 humpback

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Some of the tools we used to investigate the Kaldfjord ecosystem, from the echo sounder towed behind the boat,

whales, the killer whales, and the fin whales visiting the fjord the same winter consumed about 36 000 tonnes of herring, a number very similar to the herring catches by commercial fisheries (about 37 000 tonnes in Kaldfjord/Vengsøyfjord in winter 2014/2015). Combined, whales and fisheries took approximately 5% of the estimated herring biomass in Kaldfjord and Vengsøyfjord. Prompted by the high number of whales in Kaldfjord, more than 34 whale watching tour operators emerged in the fjords near Tromsø between 2011 and 2016. The increased level of activity by whale watching vessels, numerous fishing vessels and a large number of private boats resulted in various undesirable whale–human interactions such as ship strikes and

traps and landers deployed in the water, to tags to track whale behaviour and movement. Diagram: Ingrid Wiedmann / UiT The Arctic University of Norway

entanglement in fishing gear or cables. The situation in Kaldfjord demonstrated clearly that there is a substantial need to assess local whale behaviour (e.g. diving patterns) and long-term migrations to be able to better handle whale–human interactions. Researchers in weShare contribute to this understanding in collaboration with colleagues from the University of St. Andrews (Scotland).

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Fast forward to July 2018. Kathy Dunlop and Paul Renaud are out on the fjord on a beautiful summer day, in stark contrast to the winter sampling. They are there to retrieve the long-term sediment traps that have been at the bottom of Kaldfjord for 10 months. Together with colleagues from Laval University (Canada) and aided by a powerful winch and strong crew, they quickly get their equipment out of the water, back on deck, and to the lab.

Kathy Dunlop microprofiling a sediment core from Kaldfjorden to examine sediment oxygen dynamics. Photo: Marta Maria Cecchetto / Heriot Watt University

In autumn 2016, dedicated hydrographic surveys were conducted in Kaldfjord to supplement the herring ­surveys, and in 2017, two additional Fram Centre projects joined weShare to form an integrated study of the fjord ecosystem. The project WHALE looks into the physical, chemical and biogeochemical processes in the water column, while the project EFFECTS, together with the project JellyFarm, funded by the Research Council of Norway, studies the effects of herring and aquaculture on the benthic community. Beyond providing a highly integrated and interdisciplinary collaboration, the projects also stand out for the high numbers of women among the research team, students, and early career researchers involved. Students at all levels of education (Bachelor to PhD) from UiT, the University of Oslo, and even the University Centre of the Westfjords in Iceland contribute to the different projects. Several female postdoctoral researchers took on leading roles. We thank the Fram Centre for providing additional incentive funding to support the training and network building of these young scientists.

By September 2018, a year of monthly surveys, mooring deployments and recoveries, sediment coring, and herring baiting was over: days filled with wind, waves, and waiting for the best weather window. We have undertaken research cruises on small aluminum boats, and on some of Norway’s largest research vessels, including the new icebreaker RV Kronprins Haakon. We have investigated the Kaldfjord system from the weather at the top, through the visible and non-visible things in the water column, to the fjord seafloor, its bottom-dwellers and sediments. We spent many hours in the lab analysing our samples, and even more hours in front of a computer to make sense of the numbers. Jofrid Skarðhamar and Qin Zhou (Akvaplan-niva) set up two computer models of the fjord circulation to fill in some of the gaps in our observations. The models provide information on how the currents vary in time and space, and how the water masses circulate in the fjord. Combining model results with the field observations helps us understand the physical processes that affect the transport of plankton and particle flux, and maybe even the presence of herring and whales. What we find is a surprisingly dynamic environment in this relatively small fjord. Seasonality is a major driver of the physical and biological processes in the fjord, but already from this short study, we can see large interannual variability. Master’s student Zoe Walker showed how changes in weather patterns such as winter droughts or strong unseasonal wind events have an immediate effect on the hydrography, affecting fluxes from the surface waters to the ­benthos. Organic particles sinking from the fjord

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Zoe Walker rinsing a zooplankton net.

A happy scientist: Ingrid Wiedmann and a sample from the short-term

Photo: Angelika Renner / Institute of Marine

traps after another successful deployment. Photo: Bernhard Schart-

Research

müller / UiT The Arctic University of Norway

surface provide a food supply to the fjord seafloor ecosystem and understanding the dynamics of this flux is a key goal of both short- and long-term sediment trap deployments. The traps have allowed us to resolve a clear annual seasonal pattern in carbon flux, which will prove valuable in understanding the functioning of sub-Arctic fjord ecosystems.

Kaldfjord has great value for the inhabitants of Tromsø and the coastal community thanks to its proximity and the recreational opportunities it offers, but also for aquaculture, fishing and industrial activities. Many people are very interested in our research, curious to see how our work will contribute to solutions for more sustainable use of the fjord. Analyses of our field and model data are yielding results, and the next year will be spent confirming these results, and publishing and communicating them to both the scientific and the local communities.

Postgraduate students Anouk Klootwijk and Hege Vågen from the University of Oslo studied seafloor communities, which rely on the particle food supply from the water column, and their functioning in Kaldfjord. They chose to study benthic foraminifera, which have been described as a lens into present and past environments because foraminifera are so abundant, widespread and sensitive to environmental changes. Living diatoms can in addition provide us with valuable information on present-day environmental conditions, while fossilised foraminifera give clues to past environments and allow us to examine environmental changes over the last 120 years in Kaldfjord.

Now that the herring, the whales, the fishing fleet, and the whale watching operators have moved on, other fjords are experiencing a situation similar to that seen in Kaldfjord a few years ago. Our integrated ecosystem study in Kaldfjord can provide valuable information for impact assessments and management in these areas. We hope it will also contribute to sustainable use of northern fjords, allowing fish, whales, and humans to live here together.

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Preparedness requires constant practice, like this exercise conducted in Svalbard in 2016. Photo: Norwegian Coastal Administration

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Øyvind Rinaldo, Rune Bergstrøm and Vivian Jakobsen // Norwegian Coastal Administration

To the future and back: Future governance of environmental risk How can we manage environmental risk across 1 979 179 km² of ocean and 100 915 km of coastline? How can we make a contingency plan to protect this vast area? And how can we make a new plan every fourth year with comparable results? That’s what the Norwegian Coastal Administration had to figure out.

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magine that sometime in the future you want to know about environmental risks in the coastal area where you live. Your internet search shows you a map with little squares in different colours. Intuitively you know that the most intense colours signal the highest risks. You can zoom from a broad overview to details of the coastline. Click on a square and you get more information about the risk: ship traffic density, types of cargo, environmental vulnerability, what species are in the area in different seasons, how vulnerable they are, and so on. A system that can do all this is what the Norwegian Coastal Administration (NCA) is building right now.

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THE CHALLENGE: MANAGE ENVIRONMENTAL RISK

Oil recovery operations after MV Crete Cement ran aground

The NCA is an agency of the Norwegian Ministry of Transport and Communications. It is responsible for services related to maritime safety and infrastructure, transport planning and efficiency, and emergency response to acute pollution. The Norwegian Parliament expects the NCA to maintain preparedness against acute pollution, and the response must be tuned to the environmental risk at all times. With vast areas of ocean, this is a substantial challenge.

outside Fagerstrand in 2008. Photo: Norwegian Coastal Administration

To calculate the risk of an acute spill from an accident at sea one needs information about the ship (its type, size, type and amount of cargo and bunker oil, speed, distance from land and other ships), about conditions (weather, visibility, time of day/year), about risks (probabilities of collision, grounding, fire, foundering, different types and sizes of spills), and much more. The environmental risk related to ship accidents is the risk of an oil spill multiplied by the consequences for the environment. These are determined by factors like spill size, oil type, species and ecosystem vulnerability, weather, time of year, recovery time and many more. Given the huge scope of the task and the data analysis it involves, the NCA must renew its approach to environmental risk assessment. We are now replacing a scenario-based approach with a dynamic and holistic system, based on more detailed knowledge of the risk for shipping accidents and environmental vulnerability. Today’s better access to digital data and computing power allows us to go digital on most of the risk assessment process.

CONTINGENCY PLANS The purpose of making environment risk assessments and good forecasts for shipping is to build contingency plans that safeguard the environment. A good contingency plan for the NCA covers:

• Safe navigation for ships in all Norwegian waters. • Proper oil-spill recovery equipment in the right place at the right time. • Proper training of personnel. • Proper support for operational personnel from environment advisers and logistics. • Proper management for an oil-spill recovery operation.

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THE ADVANTAGES OF AUTOMATION Much of the information we need for contingency planning is available in databases. Details about ships’ position, course, speed and much more can be gleaned from AIS messages (AIS=Automatic Identification System), merged with data from other sources, and used in risk-calculating algorithms.

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Computers can be programmed to collect, arrange, and process these data automatically. This frees up our staff for tasks that match their competence, and that cannot be automated. An employee who is studying the impact of an oil spill is using her skills much more profitably than if she were setting up data for analysis. We want our staff to spend more time on activities that mitigate risk.

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Better planning tools The new tools being developed by the NCA will improve several aspects of contingency planning. • Environmental risk will be assessed for all Norwegian waters, not just for a few scenarios, as was previously the common way of doing risk assessments. Oil and ice mix after the accident involving MV Godafoss outside Fredrik-

• Contingency plans will be more adapted to the actual environmental risk at a specific time. • The process of creating plans based on the environmental risk in specific areas will become more efficient and accurate. • By connecting the environmental risk assessment with the National Transportation Plan, it will be easier to include environmental risk among the criteria for prioritising projects, thus reducing the probability of accidents related to ship traffic. • More people will gain more insight when our data, tools, methods and results are available to other government agencies, scientific research institutions, consultants and the public. • The NCA approach can be used to improve efficiency and quality in other fields of governance.

stad in 2011. Cleaning up oil spills in icy water is particularly difficult. Photo: Norwegian Coastal Administration

BROADER IMPLICATIONS OF GOING DIGITAL A digital and automated process requires accurate, quality-controlled, up-to-date information. The data must also be coded, stored, and presented in a consistent way. Corrupt, missing or incorrectly formatted data could halt the analysis or give unreliable results. This means that all our suppliers must ensure data accuracy and quality-control from start to finish. In other words, digitalisation and automation at the NCA will affect other government agencies and research institutions as well. An example: One of the NCA’s most important suppliers of environmental data is the Norwegian Environment Agency, which collates information from a wide range of research institutions. When the NCA does a risk assessment, we want to include the newest, most relevant data. Luckily, this information is easily available through “Norge digitalt” or “Geo Norge”. But are we getting the latest bird and whale counts? Are we getting the latest data on their vulnerability? These types of questions put pressure on the Norwegian Environment Agency and research institutions to stay on their toes.

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Reports and plans

AISyRisk Ship risk

Research database

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Vulnerability Ecosystems Species

Research reports and papers

havmiljo.no

Environmental risk calculation

EnviRisk Environmental risk

Beach types Other data sets

Environmental research

.

Analysis

NCA External Source This schematic diagram shows how the Norwegian Coastal Administration envisions collaborating with research i­ nstitutes and other players to attain the best possible preparedness in Norwegian waters. Diagram: Norwegian Coastal Administration; ecosystem image: Institute of Marine Research

But there are other ramifications as well. Researchers collect data with a specific purpose in mind. If the data are used for a different purpose, they might give distorted results. Hence, secondary users must learn how data sets are built, what they are intended for, their strengths and limitations. When a data set has been available for a while, new possibilities are often discovered; with a little twist, the data can meet new needs. But in an automated process, such twisting requires redesign and alterations of the entire data supply chain. Without cooperation between data suppliers and data customers, some parties will experience system failures or errors. NEW SUPPLIER–CUSTOMER RELATIONSHIPS New dependencies in the supply chain might be a new way of thinking for data suppliers. Even the thought of being part of a supply chain might be a change of paradigm. However, this is one of the implications of digital processes in governance and other types of business cooperation. Where the Norwegian Environment Agency used to make a data set available and be

done, they now have to consider several customers and uses of their data. New dependencies will limit the freedom to change the layout of a data set from one version to the next. They might even limit the freedom to explore new possibilities in analysis or graphical presentation of data. Before any change is made, some of the important users will have to be consulted to evaluate its potential impact. Are digital processes, automated risk assessments and new tools a benefit to all, or will this be an undue added burden for the data owners? When we discuss with scientists and data owners, we hear that they appreciate our use of their data; it is a confirmation that the data are important and will usually help them get the funding required to update and extend their data sets. When science meets governance – when research data are put to use in management plans and reports – this often creates new demands for data, and new possibilities open up. Elaborating these possibilities early

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in the planning phase might lead to a better project. Likewise, if standardised coding, storage, and formatting of data sets is implemented into the research design, Norwegian society will save money on a more streamlined process from research to governance. Having a pre-planned path from research to policies being made by the Norwegian parliament has to be a goal for some of the research.

The methodology, data and process will be open to scrutiny. Our intention is both to provide a useful tool, and to receive input and ideas on how to make our analysis and assessments better over time. Sharing and cooperation will save money and help others with similar needs for risk assessments. We hope that other agencies will see new possibilities and develop other tools or help us evolve our risk assessment tools.

A MORE OPEN GOVERNANCE

This openness will also give others insight into how the NCA constructs its oil spill contingency plans. The NCA believes that an open governance builds trust.

The new environmental risk assessment tool currently being developed by the NCA will be available for other government agencies, NGOs and researchers.

One of the North Atlantic’s largest breeding populations of Brünnich’s and common guillemots faced an acute threat when the freighter Petrozavodsk ran aground at the southern end of Bjørnøya. Photo: Harald Steen / Norwegian Polar Institute

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Recovery operations must sometimes be done under extremely challenging conditions. The trawler Northguider ran aground in Hinlopenstredet in northern Svalbard in late December 2018. The crew of 14 were evacuated safely by helicopter. Within just over two weeks – despite stormy weather, extreme cold and the perpetual darkness of the polar night – the ship had been emptied of marine diesel and other hazardous substances. Photo: Norwegian Coastal Administration

Ongoing Work Towards the New Governance The NCA is conducting several projects working together towards a digital and automated risk assessment. The result will be a ship and environment risk assessment tool made of three modules. All will have a resolution of 10 × 10 km, and coastal regions will have 1 × 1 km resolution. Values can be aggregated to larger areas. To cover seasonal changes, we will adopt a one-month resolution for both historical and future assessments. AISYRISK AISyRisk is a module for assessing the risk related to ship traffic. It utilises AIS-data, information about the ship, weather data, historic accident statistics, and advanced algorithms to calculate the probability of ship accidents, risk of an oil spill and loss of life. Probabilities and risks for collisions (head on, overtaking and crossing), grounding (powered and drifting), fire, foundering and loss of life due to accidents are calculated.

ENVIRONMENTAL RISK (ENVIRISK) The EnviRisk module utilises data from AISyRisk, environmental data from havmiljo.no, other environmental data sets, and oil drift models to calculate environmental risk. The system will give users the possibility to drill down from an overview to detailed information about the area, ecosystem, species, vulnerability and estimated recovery time. NEW FORECASTING MODELS FOR SHIP TRAFFIC The forecasting model currently being used by the NCA gives a linear forecast based on economic growth and growth in transported goods. It is assumed (but not confirmed) that the change in transported goods has a 1:1 relationship with sailed distance for the appropriate ship types. The temporal and geographic resolution cannot provide the details we need for environmental risk assessments. Therefore, we are looking into new models for forecasting ship traffic. A model based on the combination of historic AIS data, statistical ensembles for forecasting, economic growth and growth in transported goods is so far the best alternative. The forecasting module is important to foresee future risk.

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Lawrence Hislop and Gwénaëlle Hamon // CliC - The Climate and Cryosphere project of the World Climate Research Programme

Engaging users of sea ice forecasts to improve next-generation products and services Increasing uncertainty about future sea ice conditions presents a distinct challenge to industry, policymakers, and planners responsible for economic, safety, and risk mitigation decisions.

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he ability to accurately forecast the ­extent and duration of Arctic sea ice on different time­scales provides significant implications for the operation of wide-ranging Arctic maritime activities. In the last decade, the complexity of methods used to make sea ice predictions has increased considerably, with many new contributions from the modelling community. But are these developments finding their way into better forecast products that meet the specific needs of the individual stakeholders composing the forecast user community? What is actually needed to ensure the safety of the crew and ships operating in ice-covered waters, to comply with international standards and regulations, and to enable sustainable economic development?

To explore ways to improve the utility of sea ice forecasts, a small group of partners (listed below) in sea ice research and forecasting organised a workshop during the Arctic Frontiers conference in Tromsø, Norway in January 2018. The main goal was to bring together sea ice forecasters and stakeholders, to have an open discussion on what is possible to achieve with current forecasting systems and how to better meet stakeholders’ needs. Many other complementary projects are also focusing on this topic, and the hope is to link communities, share workshop results, and follow up with more dialogue.

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Sea ice chart of Svalbard for 23 January 2018. In contrast to forecasts, typical ice charts like this one are derived from nearreal-time satellite observations. Source: Norwegian Meteorological Institute – MET Norway Norwegian Ice Service

OVERARCHING QUESTIONS AND WORKSHOP FORMAT The organising committee for the Arctic Frontiers workshop assembled a cross-section of forecasters from Europe and North America along with key representatives from the private sector to discuss emerging issues and highlight opportunities. The workshop focused on creating an engaging dialogue and gathering feedback from all participants in order to get a better understanding of current and future user needs. Some of the overarching questions addressed at the workshop included: • What is the economic value of current forecasting systems? • How are forecasts used in decision-making, and if they are not used, then why not? • What are the limits and opportunities associated with current forecasting systems? The half-day workshop was organised around individual presentations in the first section, to help set the

stage and introduce some key discussion items. This part focused on the capabilities of sea ice forecasting products and was followed by presentations on user and stakeholder needs from an operations and management perspective. The second section was structured around small breakout groups that discussed the overarching and more specific pre-selected questions. The last part of the workshop was a series of plenary presentations summing up the discussions and conclusions. ENSURING SAFETY NEEDS BETTER COMMUNICATION Paramount for all industries was ensuring the safety of the crew and ships operating in ice-covered waters, complying with the Polar Code, and following related international standards and regulations. The benefits of accurate sea ice forecasts were therefore highly valued for safeguarding the passage of vessels, improved logistics planning and overall efficiency. Participants noted the importance of forecasts and the help they can provide in saving fuel and time as well

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Participants in breakout groups during the second half of the workshop. Photo: Lawrence Hislop / Norwegian Polar Institute

ice and overall quality of ice. There was consensus among the participants that the human aspect of interpreting and conveying information in the right ways could dramatically improve these issues going forward. Increased dialogue between forecasters and the user community is essential for developing new products and services that can help with short- and long-term planning.

as in ­reducing costs of maintenance and insurance. Moreover, the need for real-time information on the current sea ice state and for small-scale and high-resolution products was highlighted. Companies ultimately need to know if they can get through a very specific area, e.g. straits, bottlenecks and essential gateways. Therefore, knowing the ice thickness and strength in real time at a specific location and where the marginal ice zone transitions into pack ice is critical to moving ships safely and efficiently. An overarching need identified by many of the participants centred around improved communications, both on the technical side and regarding human capacity/ability. North of 79° the main form of telecommunications is with Iridium technology and the data transfer rate is only 30 kb/s – which can be very limiting (especially for high-resolution and real-time information). Any new forecast products or services will need to consider these limitations. Companies would also like more standards and agreement among forecasters concerning how to define important parameters such as the ice edge, first-year vs multi-year

In the future, the event organisers are looking to establish cooperation opportunities with the participants and to develop a longer-term strategy for continued engagement between these communities. There are many opportunities for improvements in the reliability of sea ice forecasts and an eagerness amongst users to help tailor products that suit their needs. Such dialogue and enhancements should lead to better-informed stakeholder decision-making, safer passage of vessels and sustainable economic ­development.

The following workshop sponsors are acknowledged: University College London (UCL), the Arctic Research Consortium of the United States (ARCUS), the Norwegian Ice Service – MET Norway, the Bjerknes Centre for Climate Research, the Climate and Cryosphere (CliC) project of the World Climate Research Programme (WCRP), EU-PolarNet and the Research Council of Norway.

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Ships travelling in and near the ice require information on sea ice that includes highresolution metrics on sea-ice edges, drift, pressure ridges, open water areas (leads), ice age, ice thickness and snow depth. This is true for both operational vessels such as the Canadian ore-bulk-oil carrier Arctic, and research vessels like Lance, seen here anchored to an ice floe during the INTPART cruise of 2017. Photos: Tim Keane (above) and Lawrence Hislop / Norwegian Polar Institute (left)

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JoLynn Carroll, Starrlight Augustine and Geir Morten Skeie // Akvaplan-niva Frode Vikebø and Daniel Howell // Institute of Marine Research Raymond Nepstad and Ole Jacob Broach // SINTEF Radovan Bast // UiT The Arctic University of Norway

Assessing the consequences of oil spills on commercial fish The fisheries industry regularly harvests a share of managed commercial fish stocks. Fram Centre researchers examined the impact of oil spills on Norway’s main commercial fisheries, the Northeast Arctic cod, using an advanced simulation technology.

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ach spring, northeast arctic cod (Gadus morhua) travel from the Barents Sea to spawn further south along the Norwegian coast from Møre to Lofoten, releasing millions of eggs into the ocean. These eggs then begin their own journey, developing into fish larvae as they drift with the currents, north and east towards the Barents Sea. The journey is perilous and their chance of survival is small. For every million eggs, only about 800 larvae survive the first half year. Their fate depends on the movements and prevailing environmental conditions of the North Atlantic Current, the accessibility of prey to feed upon, and their ability to avoid predators – including their own species. Only about 60 per million fish larvae live through their first year and only about 6 per million young cod successfully enter into the Barents Sea population at about 3 years of age.

HUMAN ACTIVITIES IN THE COD HABITAT The Northeast Arctic cod has been commercially fished for centuries. Its habitat overlaps with marine areas containing more than half of Norway’s new and unexplored petroleum resources. Norway’s marine environmental policy aims to balance the needs of different user groups while maintaining the health of the ecosystem. While the impact of commercial fishing is regulated and assessed annually through monitoring surveys, major oil spill events occur rarely, under unique circumstances, and with complex outcomes. It has proved challenging to apply experience acquired from previous major oil spills to plan for and respond to potential future spills. After the Exxon Valdez and Deepwater Horizon oil spills, scientists recommended the development of ecosystem-oriented s­ imulation

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Northeast Arctic cod (Norwegian: skrei) Photo: Lars Olav Sparboe / Akvaplan-niva

technologies to assist with oil spill planning and assessment. Simulation technologies provide the quantitative capacity to examine dynamic processes and to extrapolate from individual effects to population impacts. SIMULATION TECHNOLOGY FOR IMPACT ­A SSESSMENT Sustainable management of the cod population requires assessment of the combined risks and impacts from oil spills, together with losses through natural mortality and fisheries. The simulation technology “SYMBIOSES” was developed for this purpose by Fram Centre partners: Akvaplan-niva (project lead), Institute of Marine Research, SINTEF, and UiT The Arctic University of Norway, and 13 international

­ artners. The developers applied an innovative p strategy of linking four well tested, state-of-the-art models into a framework, and used the latest results from laboratory exposure studies to assess the toxic effects of oil compounds on fish eggs and larvae. The framework encompasses unique predictive capabilities because it is tuned with fisheries data collected annually since 1985 as part of Norway’s stock assessment monitoring programme. Researchers simulated over 150 major oil spills discharging between 17 and 350 metric tonnes of oil into the main spawning area. All scenarios start at a vulnerable time of year: the beginning of the spawning season in late March. The scenarios include years when the recruitment of juveniles into the Barents Sea cod population was high, medium, and low.

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Facts about SYMBIOSES SYMBIOSES is an impact assessment simulation technology for the investigation of oil spills and their impact on fish populations SYMBIOSES increases scientific understanding in support of the ecosystem approach to marine management SYMBIOSES was developed by Fram Centre partners: Akvaplan-niva (head of project), Institute of Marine Research, SINTEF, and UiT The Arctic University of Norway, together with 13 international partners SYMBIOSES includes four state-of-the-art models: • oil fate and transport • ocean dynamics • movement and development of fish eggs and larvae • multi-species population interactions SYMBIOSES has been applied to the Northeast Arctic cod population and its spawning areas in Lofoten–Vesterålen SYMBIOSES will be developed for several additional fish species (haddock, herring, capelin, saithe, polar cod) and with further improvements in the ecological realism

CONSEQUENCES FOR THE COD POPULATION Fish life history characteristics, such as egg transport, life stage duration, spawning frequency, and spawning–recruitment relationships, determine the resiliency of a fish species to population fluctuations. For Northeast Arctic cod, natural causes underlie the mortality of 99.9% of the spawned eggs. And even though commercial fishing currently harvests about 25% of the biomass of the Barents Sea cod stock each year, this population is among the world’s largest and healthiest. For the assessment of impacts from oil spills by SYMBIOSES, four different parameter sets were applied to account for how fish eggs and larvae are affected by exposure to lethal and sub-lethal concentrations of toxic oil compounds. Two of the four parameter sets had no apparent impact, while the other two sets reduced cod biomass by up to 12%. As a whole, however, the cod population remained healthy, with a sufficient number of juveniles surviving to replenish the population through spawning. We concluded that the diverse age distribution and health of cod stock in the Barents Sea renders this population resilient to the combined losses from natural mortality, commercial fishing and the simulated individual oil spills. IMPACTS ON OTHER FISH SPECIES From the beginning, the vision of SYMBIOSES was to create an advanced simulation technology for the assessment of oil spill impacts on the cod population that would include greater ecological realism. The simulated impacts on the cod population must be applied cautiously, particularly in a management context, as simulations are inherently simplifications and incorporate the limitations in our current understanding of complex natural processes. SYMBIOSES can and must continuously evolve in step with the latest research developments. The developers plan to extend SYMBIOSES to evaluate additional fish species. Recent scientific achievements in the fields of marine biology, fisheries, marine ecology, and ecotoxicology, along with more powerful supercomputers, provide the necessary foundation to begin working on several species: haddock, herring, capelin, saithe, and polar cod. Extending SYMBIOSES to more species opens the door to addressing a wider

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The model domain. The location of oil releases is 67.700N 10.841E (black star). Nine cod spawning locations are also highlighted (red dots). The inset graph shows the range of losses of cod biomass resulting from the application of four effect parameter sets (P1-P4) to cover a wide range of uncertainty in effects threshold values.

Conceptual representation of the SYMBIOSES simulation technology.

range of lethal and sub-lethal effects with respect to multi-species impacts, predator–prey interactions, and competition, to achieve a more ecologically relevant view of potential oil spill impacts for Norway. Discrete advances in research knowledge and their incorporation into decision-support simulation technologies aid our ability to synthesise and extrapolate the understanding of how human actions translate into environmental impacts. This in turn will allow humans to foresee and thus better prepare for events, consider how to modify actions, and evaluate appropriate mitigation measures should an accident occur. These proactive measures provide practical benefits for society and support the objective of sustainable management for northern Norway’s marine-based economy.

FURTHER READING: Carroll J, Vikebø F, Howell D, Broch OJ, Nepstad R, Augustine S, Skeie GM, Bast R, Juselius J (2018) Resiliency of a healthy fish stock to recruitment losses from oil spills. Marine Pollution Bulletin 126: 63-73, https://doi.org/10.1016/j. marpolbul.2017.10.069 Update of the integrated management plan for the Barents Sea–Lofoten area including an update of the delimitation of the marginal ice zone Meld. St. 20 (2014–2015) Report to the Storting (white paper) https://www.regjeringen.no/ contentassets/d6743df219c74ea198e50d9778720e5a/en-gb/ pdfs/stm201420150020000engpdfs.pdf

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Morgan L Bender and Jasmine Nahrgang // UiT The Arctic University of Norway, Institute of Arctic and Marine Biology Marianne Frantzen // Akvaplan-niva Schematic diagram of the

Polar cod early life stages up against a changing Arctic

experimental design with water temperatures of 0.5°C (blue panel) and 2.8°C (red panel). Column A) 32 incubators containing four different concentrations of dissolved crude oil (PAHs); Column B) polar cod eggs 15 days post fertilisation; Column C) larval length and phenotype at hatching. Diagram: Morgan L Bender / UiT The Arctic University of Norway

Transparent eggs floating just beneath the ocean’s surface signal the beginning of life for one of the Arctic’s most abundant pelagic fish: polar cod. Throughout the Arctic, these small fish form the basis of many seabird, seal, and whale diets. How will the millions of eggs and larvae handle future stressors?

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he life of a polar cod starts during the polar night in a cloud of eggs and sperm released by their parents. Despite the ecological importance of polar cod, their spawning behaviour is relatively unknown. Fertilisation of the eggs by the highly active sperm marks the start of a long (60-day) incubation period at the surface of the ocean, beneath sea ice. Upon outgrowing their protective egg shells, small larvae wriggle out and rely on their large nutrient-rich yolk sacs to give them time to develop and grow before they must start to actively feed. With luck, the timing of fertilisation and hatching puts the 5-mm long larvae in a prime spot to feast on the spring bloom of copepod nauplii in the upper water column. Within months, the larvae become quicker, more ­pigmented, and metamorphose into juvenile polar cod before descending to depth as mature individuals.

DEFINING SENSITIVITY Eggs and larvae are sensitive. They must quickly achieve many developmental milestones, but have a limited energy supply, and are unable to move away from threats. The risk of embryos coming in contact with dissolved oil components from accidental petroleum discharges or passing ships is greatest in surface waters. Simultaneously, the extent of their habitat – sea ice – is shrinking in the Arctic owing to warming surface waters. Even low levels of pollutants and minute changes in temperature can have irreversible effects on the early development of fishes. To assess the sensitivity of early life stages of polar cod from fertilisation to active feeding, we conducted a 170-day trial where embryos were exposed both to low levels of crude oil dissolved in water and to water 2.3°C warmer than

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0.0 ppb PAHs

0.1 ppb PAHs

B 15 days post fertilisation Fertilisation / Exposure start

Experimental design of incubators

0.5 ∘C

A

500 µm

C

Larval length at hatch

5.7 ± 0.3 mm

62 days to hatch

2.8 ∘C

Increasing concentrations of crude oil

0.0 ppb PAHs

0.2 ppb PAHs

their optimal development temperature of 0.5°C. Our aim was to assess the sub-lethal physiological and behavioural effects that thermal stress has on the sensitivity of embryos and larvae to petroleum pollution. HOW LOW CAN WE GO? This study underscored the glacially slow embryonic development of polar cod, testing the patience of even the most dedicated researcher. Meanwhile, the water temperatures we used were low enough to replicate the frigid environmental temperatures where polar cod embryos thrive. Our warmest water hovered at a teeth-chattering 2.8°C – a “hot” temperature that has already been seen north of the polar front in the Barents Sea. The crude oil levels we used were infinitesimal. Concentrations of polycyclic aromatic hydrocarbons in the water at the beginning of the experiment were an order of magnitude below what has been found after accidental and experimental oil spills in the ice – even below water quality standards for Alaska! The polycyclic aromatic hydrocarbon levels decreased exponentially with time, reaching background concentrations by the time hatching occurred in each temperature group.

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5.1 ± 0.6 mm

30 days to hatch

The project Sensitivity of polar cod early life stages to a changing Arctic: A study of the impact of petroleum and warming (Sens2change) was supported by the Fram Centre Flagship MIKON 2018 grant (Project Sens2change). Four Fram Centre institutions and many national and international partners are involved, including UiT The Arctic University of Norway (J Nahrgang and ML Bender), ARCEx (NFR 228107) (M Frantzen), and the EWMA project (NFR 195160). A visual log from the Sens2change project can be found at: facebook.com/Sens2change/ instagram.com/sens2change/

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B

A

2 mm

Polar cod larvae reared at 0.5°C, one month after hatching: A) control unexposed and B) exposed to 0.1 ppb of dissolved crude oil. Images: Morgan L Bender / UiT The Arctic University of Norway

DISENTANGLING EFFECTS Statistical models allow us to explore the effects of a multi-stressor experiment on many aspects of the early biology. Temperature has a profound effect on the timing of development for such a cold-water species. With a difference of 2.3°C, we found a full month difference in hatching time. Our data reveal that embryos incubated at 2.8°C hatched in a less developed state, not taking the time to develop a face and jaws until after hatching. Larvae got their sustenance from their large yolk reserves until they could begin active feeding. We found that even at our miniscule exposure levels, equivalent to just 0.2 ppb of polycyclic aromatic hydrocarbons, egg buoyancy, larval growth, survival, onset of feeding, and behavioural response to additional stresses were affected. Lastly, increased prevalence of deformities and decreased feeding activity eventually led to starvation and death several weeks after hatching. WHAT’S WORSE FOR POLAR COD, HEAT OR OIL? Comparing the multigenerational, long-term changes that a warming climate might evoke, and the possible effects of an acute, local oil spill – studying both in the

same experiment – is not a simple task. We see that sub-optimal (i.e. warm) temperature alters the timing and development of polar cod and increases their sensitivity to low levels of petroleum pollution. However, the population-wide impact of adverse effects on early life stages of polar cod is more complex. Compared with their bigger cousin the Atlantic cod, female polar cod produce fewer but larger eggs – and their personal investment is extremely high. In fact, both male and female polar cod invest over half their body weight into their reproductive organs as spawning nears. Thus, polar cod may not be as resilient to having a bad batch of eggs and larvae as other fish species, such as Atlantic cod, who have more eggs per batch and can spawn many times over their long life. Polar cod in the Barents Sea have already exhibited population decline and altered life history in warmer, more Atlantic-influenced areas of the Arctic. Although spawning locations may shift northward to ensure the low temperature embryos need for development, there is no guarantee that these areas will provide adequate nursery and feeding grounds for larvae. While this may be speculation, the studies in our lab indicate that in a warmer, more polluted Arctic, the early life stages of polar cod will feel the heat.

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A local high school class visited the lab to learn about polar

PhD candidate Morgan L Bender evoking empathy for

cod and the sens2change experiment.

deformed fish at Tromsø’s Researcher Grand Prix in

Photo: Morgan L Bender / UiT The Arctic University of Norway

September 2018. Photo: Eskil Mehren / Nordlys

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Communicating the process Spending 170 days in an Arctic-simulating wet lab babying organisms almost too small to see may be a common experience among polar researchers, but we thought we should share it beyond our traditional circles. We therefore invited several local high school classes to join us for parts of our experiment. Four

Master’s students were involved in all aspects of the experiment and helped manage our social media presence on Facebook and Instagram. Additional attention was brought to the project through the newspaper Nordlys and through the regional Research Grand Prix competition in Tromsø.

FURTHER READING: Nahrgang J, Dubourg P, Frantzen M, Storch D, Dahlke F, Meador J (2016) Early life stages of an arctic keystone species (Boreogadus saida) show high sensitivity to a water-soluble fraction of crude oil. Environmental Pollution 2018: 605-614, https://doi.org/10.1016/j.envpol.2016.07.044

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Vera Schwach // Nordic Institute for Studies in Innovation, Research and Education Olav Sigurd Kjesbu // Institute of Marine Research

Johan Hjort: a marine research pioneer whose ideas still hold water One hundred fifty years have passed since the birth of Johan Hjort (1869-1948). Best remembered for his groundbreaking theory from 1914 on the natural fluctuations of fish stocks, Hjort paved the way for materials and methods that are used to this day, not least in climate studies.

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ohan hjort was a marine zoologist, the first head of the Norwegian Directorate of Fisheries and an important figure in building national and international institutions. While at the Directorate, he worked to modernise fisheries. Research was an important element in building a useful knowledge base, and a key tool for enhancing profitability and scaling up the industry. Hjort’s efforts within marine research focused on seasonal fishing for cod and herring. These fisheries were of great economic importance to Norway and a research focus for Hjort and those who later followed in his footsteps. As a marine scientist, Hjort formulated bold hypotheses and made use of opportunities close to home. And he loved being at sea.

subject to natural variations has been the basis for over a hundred years of research into which physical and biological factors determine the size of a year’s class, i.e. the number of new individuals who join the fishable part of the population each year. Hjort examined herring, cod and other codfishes in the Norwegian Sea. His theory would later be tested on other fish stocks and species. Hjort was the mastermind, but he conducted his research with a small group of researchers at and outside the Directorate of Fisheries, and in collaboration with the International Council for the Exploration of the Sea (ICES).

At the outbreak of the First World War, Hjort presented an explanation of the natural causes of the great fluctuations in catches of fish; this led to a fundamental shift in the way we understand fish biology. His theory that recruitment of juveniles to fish stocks is

Hjort was strongly influenced by his scientific background, his social mandate and his political views. In a broader economic, cultural and research policy context, the ocean and fish are among several examples of the role that science and other professions have

WHERE FISH AND SCIENCE MEET

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Johan Hjort during his time in Bergen, portrait

Talented colleagues and an intellectually stimulating environment

probably taken around 1905.

factored strongly into Hjort’s success as a researcher. In the spring

Photo: Institute of Marine Research

of 1903, he and his colleagues posed for a group photograph. Back row left to right: Alf Wollebæk, Bjørn Helland-Hansen, and Haaken Hasberg Gran. Front row left to right: Knut Dahl and Johan Hjort. Photo: Institute of Marine Research

played in the emergence of modern Norway. Marine research in Norway was influenced by the structure of the nation’s fisheries, their economic importance – and the biology of herring and cod. The fisheries were vital to the national economy, especially in the 1800s. Landed catches alternated between good years and lean years. Fishermen and scientists asked themselves why the catches changed so much from year to year. In Europe, the greatest concern was for overfishing. Were the North Sea and the Baltic Sea being overexploited? Would there soon be no fish left? It was the search for natural explanations to the variations that brought Hjort and his older colleague Georg Ossian Sars (1837-1927) to the forefront of research. The Norwegian authorities feared reduced migration of cod and herring to the coast, leading to a corresponding reduction in export earnings. The importance of fisheries on a national scale, along with senior civil servants’ faith in the usefulness of scientific

­ nquiry, explains the parliament’s decision, in 1860, e to fund a permanent commission tasked with researching the natural conditions that supplied fish for the fisheries. A milestone was reached in April 1900 when the parliament created a professional trade management office for saltwater fisheries, based in Bergen: the Fisheries Commission (Fiskeristyrelsen). Six years later, the Commission was renamed as the Directorate of Fisheries (Fiskeridirektoratet). Marine research was a unifying hub in the management of a geographically dispersed and complex industry. Science assumed a strong position within the Directorate, and marine research – always costly – gained both a foothold within national institutions and access to funding outside the meagre budgets of academia. That strengthened the position of research. The Directorate of Fisheries also conferred other research advantages: it had the attention of politicians,

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Michael Sars, Norway’s first ship specially dedicated to research, began serving as a research vessel in 1900. Originally an English trawler, this retrofitted ship served as a model for fisheries research vessels in all ICES’ member states. In this photo she lies at anchor in a fjord somewhere along the Norwegian coast. It is a holiday and flags are flying on board and ashore. Photo: Institute of Marine Research

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Photomicrographs of scales from Atlantic herring,

Panel B shows age reading of a scale from a 10-year-

a historic scale on the left, and a modern scale on

old Norwegian spring-spawning herring. The dots

the right.

mark the winter rings.

Panel A shows the assumed relationship between

Photo: Institute of Marine Research photo archive;

the distance between winter rings and fish growth.

annotation Jostein Røttingen and Jane Aanestad

Photo: Einar Lea; inset drawing from Hjort 1914

Godiksen / Institute of Marine Research, Bergen

ensured availability and proximity of expert fishermen and seafarers, and easy access to the Northeast Atlantic and the North Sea, as well as facilitating sea voyages. Involvement in an international community of professionals, specialised focus – and a revolutionary new method that cut a Gordian knot within fishery research – also helped Norwegian marine scientists take the lead in the international marine research. SIGNIFICANT SCALES

in trees. But the scales had another story to tell: the pattern of distances between the annual rings could also reveal a fish’s origin. We know this because of systematic mapping done on herring in Norwegian waters, where the question was whether herring consisted of one stock or several. The herring’s scales and otoliths provided identical information about age, but the zones in the scales were easier to count. In 1904, Hjort came up with the idea that herring scales could be used both to identify distinct herring stocks and to determine a fish’s age.

Zoologists had known since 1900 that growth rings could be observed on fish scales, otoliths and vertebrae. But Hjort and his colleagues were the first to demonstrate that these rings were in fact annual growth zones. A fish’s age could therefore be determined in the same way as one counts annual rings

Hjort’s results on herring put him at the international forefront of marine research, as several of ICES’ European member states had significant herring fisheries. Studying herring was one way to demonstrate the economic benefits of marine research and focus the field’s expertise on solving a joint problem. Hjort’s

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The Norwegian parliament agreed to fund Michael Sars on condition that the ship would be used to study whales. This photo shows Johan Hjort taking notes, probably at the whaling base in Mehamn early in the spring of 1901. He is standing in front of a North Atlantic right whale (Eubalaena glacialis). This species is currently endangered; only about 350 individuals remain, mostly along the east coast of the United States. Photo courtesy of Nils Lid Hjort

assistant Einar Lea perfected the method, standardising collection and reading of results for ICES. Winter rings were darker and more clearly delineated than summer rings; therefore, age was read by winters. Hjort had some luck in 1904 when nature gave the researchers a strong year class of what is now called Norwegian spring-spawning herring. This year class could be monitored as a distinct peak in Hjort’s data on catch composition.

analysis. This criticism angered Hjort – he was a temperamental person – but it probably honed the quality of Lea’s methodological studies. It wasn’t until around 1930, that ICES (and thus also international marine research) accepted Hjort’s method. By then he had been reading fishes’ ages in scales for a quarter of a century. The moral of the story is that research (and, not least, recognition) often takes many years. THE QUESTION OF RECRUITMENT

Hjort’s focus on the scale method met with interest, but also resistance from ICES. Especially, a group of British zoologists objected to the idea that the zones on the scales actually represented annual growth rings. They also criticised Hjort and his team for a perceived lack of competence in statistics. Most members of the Norwegian group were zoologists without in-depth knowledge of statistics beyond descriptive

What determines recruitment into fish stocks is still largely an unresolved question. We now know a lot about how populations are replenished each year, but not the degree of interaction between the countless environmental factors that lead to a few years with very strong year classes and another year with very weak classes. In Hjort’s vocabulary, this is called

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Otolith from a 9-year-old Northeast Arctic cod sampled at the main spawning ground in Lofoten in 1994. The age is revealed by the number of winter rings, here marked by dots. Photo: Côme Denechaud; annotation Côme Denechaud and Jane Aanestad Godiksen / Institute of Marine Research, Bergen

“natural fluctuations” or “number of offspring”. The concept of recruitment was probably established after 1945. Research on recruitment will continue simply because it is a key factor in predicting future stocks. The central question is how large the recruitment will be next year and in following years, which in turn sets constraints on how much fishermen can harvest from the sea, in the form of quotas.

involves countless random factors and a single minor change can have major consequences over time. Nevertheless, age determination will continue to be an essential part of stock monitoring and subsequent calculations. We need to continue monitoring the formation and development of new year classes.

Although we currently have a vast array of tools at our disposal – satellite observations, theoretical ecology, genetic analysis, hydrophones on board state-of-theart research vessels, and highly complex ecosystem models – recruitment is still poorly understood. It is impressive how Hjort often arrived at conclusions that would later prove to be correct, especially for northerly latitudes. Pragmatically speaking, we will probably never fully understand the recruitment process: it

Hjort’s efforts to establish time series have had far-reaching implications for studies of marine stock and the environmental history of oceans and seas. He would have been astonished if he knew how many marine scientists have used and re-used herring scales and otoliths.

A TREASURE CHEST OF SCALES AND OTOLITHS

Scales are still used to assess stocks of Norwegian spring-spawning herring – a routine continuation of

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Otoliths must be extracted from the cod before they can be studied. Senior engineer Tomas de Lange Wenneck from the Institute of Marine Research is hard at work during a research cruise. Photo: Institute of Marine Research

a tradition that started in 1904. Otoliths and vertebrae are also examined to better distinguish between different herring populations;1 for example, there are many different populations along the coast from the Swedish border to Troms. For scientists studying North Sea herring, checking otoliths is standard routine – the herring population in this area is divided into large, distinct spawning components that may intermingle for parts of the year. Today, Norway has the world’s longest time series on the population size of marine fishes, represented by spring-spawning herring and cod (skrei). This is thanks to the targeted collection of scales and otoliths and associated biological information – fish maturation status, weight and length – as well as good catch statistics and monitoring of fishing activities. All this has been going on since Hjort’s time. Fortunately, Russia began regular hydrographic measurements in the Barents Sea in 1900, establishing the data set oceanographers call the Kola Section. This means we have two uniquely long time series for the Northeast Atlantic that make it possible to study and find connections between various changes in ocean productivity.

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The concept of population overlaps with the concept of stock, but marine scientists often use the term stock when referring to fish and other marine animals that are harvested commercially.

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The Institute of Marine Research has many shelves full of scale and otolith samples. Today’s marine researchers can use this material to answer current research questions – and the boxes will remain on the shelves waiting to provide answers to questions that have not yet been asked. Studies within theoretical ecology have already demonstrated that populations under heavy pressure from fishing change by means of local adaptations. Microscopic remnants of DNA from archived otoliths (and scales) are now being used to clarify evolutionary (genetic) changes from the early 1900s, when there was essentially no fishing, through several decades of increasing harvests, to today’s well-regulated fisheries. The University of Bergen is home to otoliths hundreds of years old and thus important in an even longer time frame. TIME SERIES AND CLIMATE CHANGE Hjort and his colleagues used fish scales and otoliths as birth certificates for fish. They could never have imagined how this material can now be put to use in research. Exciting new fields are opening up, such as otolith microchemistry, where different isotopes extracted from the otoliths give clues about what a fish has eaten, or what physical environment it lived in. If used on selected material from the historical archives of fish scales and otoliths, this methodology can – at least theoretically – provide a long and truly unique biological time series. Data from time series are crucial for scientists who wish to develop scenarios for the future. Long time series are particularly important as historic reference points; they provide background information that will be required to interpret the effects of climate change, not least in the northern latitudes.

RETROSPECTIVE

PAST, PRESENT, AND FUTURE, ALL IN ONE A little more than a hundred years ago, Hjort and his peers gathered knowledge that forms the basis for current marine research and fisheries management – nationally and internationally. He was the right man, at the right time; his social mission, proximity to the fisheries industry, and willingness to create an international professional community, combined with his transformational theory and methods, laid the foundation for Norwegian marine research. Although Norway’s position has seen periods of progress and stagnation, Johan Hjort’s position remains strong. Since his time, several new methods have evolved and his theory from 1914 has been elaborated and refined – but it has not been replaced. Hjort’s paper is now considered an international citation classic. Marine scientists in 53 countries have referred to him, and even now, a century later, Hjort 1914 is cited about 40-50 times a year. This is exceptional for a scientific publication. We celebrate the 150th anniversary of Johan Hjort’s birth in 2019. One question for the Institute of Marine Research/ICES anniversary in Bergen in June is whether his 1914 theory has reached the limit of its usefulness and should be replaced, or if it remains valid. Do current fisheries research and fisheries management need a new theory for a holistic, ecosystem-based approach in light of climate change and the significant alterations we expect in the marine environment?

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Ola Magne Sæther, Håvard Gautneb, Tor Erik Finne, Ola Anfin Eggen, Maarten Broekmans and Malin Andersson // Geological Survey of Norway, Trondheim

Roundness of mineral particles in subsea tailings from copper mining Copper mines obviously yield copper, but they also produce waste material – tailings – which must be disposed of somehow. In Norway, tailings have often been dumped in fjords as an alternative to disposal on land. The environmental impact of this practice over time is not known.

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lveryggen cu mineralisation in Repparfjord within Kvalsund municipality in Arctic Norway was discovered around 1900. Mining operations took place from 1972 to 1978, when about 3 megatonnes of 0.66% Cu was produced from four open pits. The adjacent Nussir Cu ore deposit, discovered in 1979, contains 25 megatonnes at 1.16% Cu. Tailings from mining in the 1970s were deposited at the bottom of Repparfjord. The same strategy is being considered for mines to be opened in the near future. Therefore, it is of interest to assess the environmental impact of submarine tailings disposal.

UNDERWATER DISPOSAL OF TAILINGS Submarine tailings disposal is the discharge of mining tailings below sea level. Three different types can be defined: coastal shallow-water disposal or land reclamation; submerged disposal in water shallower than 100 m; and disposal in deeper water. Norwegian authorities consider submarine tailings disposal to be a legitimate and viable alternative to terrestrial storage. Globally, submarine tailings disposal has been practiced on a large scale in several mines since the 1970s. Papua New Guinea has three active sites, while Indonesia, France, Greece and Turkey all have one each. In contrast, submarine tailings disposal is illegal in the United States and Canada, and is considered “unsuitable” in Australia.

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Sample locations in Repparfjord, Norway

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In Norway, submarine tailings disposal has long been used to get rid of waste from mining and ore-enriching facilities, and seven sites are currently active. Two more mines are being planned with submarine tailings disposal sites, one of them in Repparfjord. Mining produces vast volumes of waste – rocks from overburden, access tunnels, adits, and shafts – in addition to tailings from processed ore. Tailings are a by-product of the process of extracting ore through crushing, milling and subsequent flotation. In copper mining and extraction, the tailings account for as much as 99% of the total mined ore. The mining operation in Repparfjord will eventually be the largest Cu-ore production facility in Europe and is currently planned for 30 years of operation. Coarse masses larger than 200 µm will be used in various ways, but the plan is to dispose of the finer tailings – about a million tonnes per year – using submarine tailings disposal. PARTICLE ROUNDNESS AT REPPARFJORD

Photomicrographs of recent mineral residue from the old mine site Ulveryggen (top) and the new mine site Nussir (bottom). Photos: H Gautneb / Geological Survey of Norway

Marine biota that feed on the sea floor select food particles based on characteristics such as size, specific gravity and organic coatings. How they are affected by mineral particles in sediments (including tailings) depends on factors such as the particles’ shape, angularity and roundness. To address one potentially harmful factor, we have compared the roundness of fresh and old tailings sampled from Repparfjord with data on particles from recent sea floor and river sediments. The roundness of a clastic particle depends on the sharpness of its edges and corners, and is closely related to its surface properties. To determine the roundness of individual sedimentary particles, we examined electron microscopic images. By using automated image analysis, we were able to study a considerable number of particles.

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Inspecting a sample taken in the bottom sediment sampler. Two different corers are seen lying on the deck of the Geological Survey of Norway research vessel Seisma. The old processing plant in Repparfjord can be seen in the background, and in the close-up picture to the right. Photos: TE Finne / Geological Survey of Norway

IMPLICATIONS OF OUR RESULTS We found that the roundness of mineral particles in tailings from the old mining operations and from the recent test processing of ore from Repparfjord was similar. Moreover, the roundness of the particles in fresh tailing samples was similar to that of particles in the recent sea floor samples and in the riverine sediments. If the next mining operation produces tailings with similar particle size and roundness distribution, it is reasonable to assume that its environmental impact will be similar too, all other things being equal. Studies like the one described here are crucial in establishing a baseline for future environmental monitoring of mining operations.

FURTHER READING: Andersson M, Finne TE, Jensen LK, Eggen OA (2018) Geochemistry of a copper mine tailings deposit in Repparfjorden, northern Norway. Science of the Total Environment 644: 1219-1231, https://doi.org/10.1016/j. scitotenv.2018.06.385 https://framsenteret.no/2018/04/fate-andimpact-of-mine-tailings-on-marine-arcticecosystems-fimita/

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“There’s great potential in using drones to monitor humpbacks and other sea creatures,” says ­researcher Ana Sofia Aniceto. “The equipment can be carried to wherever you need it, and a drone can be controlled from almost anywhere: boats, oil platforms, the shore or a bridge on the coast. Drones are safer and easier to manoeuvre than large vessels. They don’t take much space and you don’t need to be near an airport.” Photo: Espen Bergersen / www.NaturGalleriet.no

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Vibeke Os // UiT The Arctic University of Norway

Monitoring whales with drones Two researchers hunker by a fjord, oblivious to the magical blue of the January twilight. All their attention is focused on an unmanned aerial vehicle – a UAV. Gloveless despite the bitter cold, they manipulate the joystick and buttons on the remote control with numb fingers, preparing the drone for take-off.

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e are somewhere on the seaward coast of Kvaløya, west of Tromsø. The sea is calm but little waves lap the shore. Out in the semi-darkness of the fjord, whales can be heard emptying their huge lungs; killer whales and humpbacks are diving for herring not far from shore. A couple kilometres from the two scientists with the drone, marine biologist Ana Sofia Aniceto sits shivering with cold high on a rocky promontory that juts out into the fjord. She stumbled up a twisting path by the light of her headlamp to find the optimal lookout. She needs to make use of what little daylight is available at this time of year. Her task is to spot the whales with her binoculars and measure the distance to those that appear on the water surface using her trusty geometer.

PREDETERMINED ROUTE The drone is controlled by experienced fingers. It is flying to the part of the fjord with the most activity; the camera on the drone’s underside snaps a picture every three seconds. The drone follows a predetermined route, flying in straight lines back and forth. Aniceto is nearby, monitoring the marine mammals’ movements with her binoculars and noting their coordinates as they move majestically through the fjord, pursuing an invisible shoal of herring. Aniceto spent many days on the mountainside overlooking Kaldfjorden in the winter of 2014/2015. The following spring, she analysed the coordinates she jotted down and correlated them with the images

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Ana Sofia Aniceto, at Akvaplan-niva, has been trying to find a good method for observing whales and other sea creatures. The project’s objective was not to study the whales’ movements and family life, but rather to develop a technology to monitor marine animals. Photo: Akvaplan-niva

taken by the drone. Come summer, she and the two drone pilots will repeat the procedures near the island of Ryøya, in far more inviting weather and with un­ limited access to daylight.

to chart the exact coordinates where an animal was located in the fjord and be certain that what we see in the image is a whale and not something completely different.”

SUPPLEMENTING EXISTING METHODS

Aniceto describes the image analysis as the most challenging and time-consuming part of the research task. “It took a long time,” she says with a smile. “But there’s definitely room for improvement,” she adds emphatically. No wonder: she analysed 4660 images manually and identified marine animals in 288 of them.

“Monitoring nature and wildlife is nothing new,” says Ana Sofia Aniceto, who works at Akvaplan-niva. She is involved in a project that tests and develops new technology to monitor marine animals. Satellites, weather balloons, land-based radar, aircraft and boats have been used to map wildlife in the past, but these methods have their limitations. Researchers are hoping to find a way to map marine animals that can supplement the existing methods. THOUSANDS OF IMAGES “We correlate and compare the pictures of each animal with observations and distance measurements done from shore as part of our study. That allows us

IDENTIFYING WHALES IS DIFFICULT Northern Norway is dark in winter, even in the middle of the day, and Ana Sofia Aniceto describes how darkness hampers image analysis. Other factors that influence their studies are waves and floating objects such as seaweed, logs and debris that form clusters in the ocean currents. Reflected sunlight also creates some uncertainty when reading images.

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Researcher and drone enthusiast Stian Solbø from Norut participated in the drone mission. He is carrying the CryoWing Scout they used to experiment with factors such as flight altitude and camera settings. Photo: Tore Riise / Norut

Aniceto thinks drones can be used in combination with other methods like acoustics and satellite imagery to great advantage. Drones can do things the other methods cannot. Satellites cover a larger area, but they are useless in cloudy weather. Acoustic methods can locate animals that vocalise, but not all whales vocalise all the time. Eventually, the researchers hope to develop digital tools that recognise whales in images – and they will use a more light-sensitive camera.

FURTHER READING: (Articles in Norwegian) Researchers use a drone to take pictures of seaweed and kelp (forskning.no): https:// forskning.no/niva-norsk-institutt-forvannforskning-havforskning-partner/forskararbrukar-drone-for-a-ta-bilete-av-tang-ogtare/1246497 Whale safari by satellite: https://forskning.no/ dyreverden-miljo-satellitter/hvalsafari-medsatellitter/1261503

The UAV project is supported by ARCEx – the Research Centre for Arctic Petroleum Exploration under Workpackage 3 - Environmental Risk Management. ARCEx (project page): http://www.arcex.no/about

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The winter monitoring of reindeer on Brøggerhalvøya started in 1978 after the reintroduction of 15 reindeer from Adventdalen. This census gives information on the total number of animals and the sex- and age distribution of the population. In 2014, the monitoring was expanded with annual captures and marking of females, which gives unique opportunities to compare reindeer responses to climate change across coastal and inland populations. In Nordenskiöld Land such long-term studies have run since 1994. COAT Infrastructure funds instruments for these studies. Photo: Odd Arne Olderbakk

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Ă…shild Ă˜nvik Pedersen and Virve Ravolainen // Norwegian Polar Institute

What can 40 years of reindeer monitoring data tell us? Svalbard reindeer live in the most rapidly changing Arctic environment. The 40-year monitoring shows population growth and increased carrying capacity of the tundra, but also harsher winters, greater isolation, and population reductions. Population developments thus diverge in the two core monitoring regions.

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Photo: Tore Nordstad

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valbard reindeer have attracted research interest for decades. Occasional counts and “guesstimates” of the population have been made since the early twentieth century, but systematic population abundance censuses did not start until the late 1970s. These annual counts have given new insight into many aspects of the ecology of the northernmost wild reindeer, which inhabits a simple trophic food web, where insects and predators have less importance than further south.

These reindeer time series form a core of the reindeer monitoring module of the Climate-Ecological Observatory for Arctic Tundra (COAT). The data have demonstrated that mainly density-dependent processes and weather variability determine the number of animals. Currently, the monitoring is being supplemented with data on individual animals obtained from capture– mark–recapture programmes in the coastal and inland monitoring regions. Combined, this information has made the Svalbard reindeer a model species to understand climate influences on Arctic herbivores.

REINDEER GROWTH RATES AND CLIMATE Rapid, dramatic climate changes have taken place since the monitoring started four decades ago. The reindeer have lived through both cold, stable winters in the 1980s, and milder, rainier winters that started to become more frequent in the 1990s, a trend that has accelerated rapidly into the new century. The increased occurrence of mild, rainy winters has led to negative growth rates through increased mortality and reduced reproduction. This is because the plants the reindeer eat become inaccessible – encased in ­solid ice for some or all of the winter season. The reindeer population crash in Brøggerhalvøya in 1993/94, for example, followed from a combination of heavy rain in early winter and overgrazed pastures. The population declined sharply to a lower level, where it has since stabilised due to an overall long-term reduction of the carrying capacity of the tundra in this High Arctic coastal region.

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In contrast to Brøggerhalvøya, the monitoring areas in Adventdalen show positive reindeer population trends over the monitoring period, despite population declines during winters with “rain-on-snow” events. In Adventdalen, the population has nearly quadrupled, with a record high number in 2018. Here, the higher summer temperatures likely play an important role in increasing the overall carrying capacity of the Arctic tundra for grazing reindeer. Plant biomass production is highly correlated with summer temperatures. Given that the summers continue to be warm and there is enough rain, we can expect food resources to remain more abundant. If autumns continue to have less snow, the food will be available longer during the autumn and into the winter. The climatic drivers – warmer summers and milder winters – will likely affect the monitored populations in different ways and cause the contrasting population developments in the monitoring areas. Currently, the time series are helping us understand how climatic drivers result in the disparate population trends seen over the last four decades.

Abundance of Svalbard reindeer in the core monitoring areas of Adventdalen (summer 1979-2018) and Brøggerhalvøya (winter 1978-2018) (http://www.mosj.no/no/). Note the sharp population decrease on Brøggerhalvøya after the rainy winter of 1993/94, and the marked increase in Adventdalen in recent years.

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SHIFTS IN SEASONALITY AND REINDEER BODY MASS The shifts in seasonality affect the reindeer in various ways – and it all comes down to how weather variability and climate affect the food supply. Herbivores owe their survival to plants – mosses, grasses and herbs that are cornerstones of the tundra vegetation communities. Warmer autumns give the animals longer snow-free seasons and better possibilities to accumulate body reserves before entering the winter, when snow makes grazing more energy-demanding. The capture–mark–recapture studies of female reindeer from the most productive areas in Svalbard, the large inland valleys of Nordenskiöld Land, provide novel knowledge on the contrasting effects of summer and winter warming on individuals and population dynamics. The winter body mass of the females explained almost all variation in the between-year fluctuations of the population growth rate because it strongly affected reproduction, which in turn affected

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Summer monitoring of Svalbard reindeer gives research and management information on the total number of animals and the sex and age distribution in the population, reproduction (calf per female rates) and mortality (carcass count). The longest time series from Brøggerhalvøya started in 1978. Photo: Bart Peeters

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subsequent survival and recruitment. A warm October positively influenced ovulation rates and a warm autumn was associated with higher body mass in April, reflecting the delay in onset of winter with the extended season for grazing without snow. In contrast, body mass in spring was negatively related to “rain-on-snow” events. The increased reindeer mortality in such years provides crucial food resources for the arctic fox, which may bring about cascading impacts on other herbivores (geese and ptarmigan) in the food web. The net outcome on individuals and their population dynamics will depend on the relative role of winter versus summer change. While continued climate warming can increase the carrying capacity of the Arctic tundra, winter processes can change the net effect of climate on reindeer population dynamics. The more frequent ground ice in winter, and winter warm spells that can melt away snow and make forage more accessible, can have differing effects depending on how much the changed winter conditions damage the forage plants. Ultimately, the outcome for individuals and populations is determined by the cumulative effects. To disentangle and separate the individual effects and the net outcome on reindeer populations, both long-term sex- and age-structured monitoring data and capture– mark–recapture data are essential. COAT REINDEER AND VEGETATION MONITORING The Svalbard reindeer population was severely depleted by hunting in the early twentieth century. Although it recovered after becoming a protected species in 1925, questions remain regarding the population’s robustness and ability to adapt to a completely new climate regime and an altered Arctic tundra landscape. Since this endemic species is a key herbivore on the Svalbard tundra, the COAT programme has focused on monitoring the reindeer, its grazing resources and interactions within the food web. The reindeer monitoring addresses direct impact pathways on reindeer survival, for example, the effects of climate (winter versus summer warming) and management (hunting quotas). Indirect impacts are also studied. Changed abundance of reindeer can affect plant communities through changed grazing

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pressure (e.g., drive the vegetation from moss- to grass-dominated); trampling and fertilisation of the tundra may also contribute to vegetation state changes. The module also addresses how the goose populations – which have grown substantially during the four decades of reindeer monitoring – might compete for vegetation resources. The vegetation monitoring links climate-related data (e.g. temperature, snow, basal ground ice, etc.) and time series of grazing animals, both reindeer and geese, to the abundance of functional plant communities and key plant species. These are examples of how the COAT programme focuses on monitoring the herbivores, the vegetation and the climate in an integrated manner. This broad, integrated approach provides knowledge about the tundra that will be crucial to management efforts. The time series of the Svalbard reindeer are an important part of this monitoring, and demonstrate how maintaining ecological data collection over time is important to many aspects of our understanding of Arctic terrestrial ecosystems.

FURTHER READING: Albon SD, Irvine RJ, Halvorsen O, Langvatn R, Loe LE, Ropstad E, Veiberg V, Van Der Wal R, Bjorkvoll EM, Duff EI, Hansen BB, Lee AM, Tveraa T, Stien A (2017) Contrasting effects of summer and winter warming on body mass explain population dynamics in a food-limited Arctic herbivore. Global Change Biology 23: 1374-1389, https://doi.org/10.1111/gcb.13435 Hansen BB, Grøtan V, Aanes R, Sæther BE, Stien A, Fuglei E, Ims RA, Yoccoz NG, Pedersen ÅØ (2013) Climate events synchronize the dynamics of a resident vertebrate community in the High Arctic. Science 339: 313-315 COAT https://coat.no

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Kathleen M Stafford // University of Washington Kit M Kovacs and Christian Lydersen // Norwegian Polar Institute Øystein Wiig // University of Oslo

Extreme diversity in the songs of Spitsbergen’s bowhead whales Bowhead whales are the only “Great Whales” that live their entire lives in the High Arctic. In the Barents Sea, this species was hunted to the verge of extinction in the first commercial whaling enterprise that started in the 1600s.

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he small size of the Barents Sea bowhead whale population, in combination with its very tight affiliation with heavy sea-ice cover, along with the challenges that arise due to the darkness of the Polar Night, leave us knowing little about the status or behaviour of the animals occupying this part of the bowhead whale’s range. But recent studies led by the Norwegian Polar Institute indicate that the population numbers in the 100s, rather than the 10s, and Passive Acoustic Monitoring (PAM) of this species, which sings as part of its mating behaviour, has led to the discovery of a “hot-spot” in the western Fram Strait during the winter breeding season. EXTREME SONG DIVERSITY In-depth analyses of three years of PAM records from Fram Strait show that bowhead whales singing at this site produced 184 different song types over the study period. Most of the songs were only present for peri-

ods of hours to days, although each year a few song types persisted throughout the winter; no song types were documented in two different winter periods. It is not currently known if individual males use a single song or multiple songs during a year, or indeed, whether they switch from day to day. Other whale species, such as humpback whales, tend to use one highly stereotyped song, which is sung by the whole population at a given time, with all animals switching to a new one when a change occurs. The song diversity seen in our bowhead whale study is “bird-like” in its complexity. No other mammals on the planet are known to produce such elaborate and varied songs. Why the songs of bowheads in this region are so complex is a mystery. The next step to solving the mystery is to see if the extreme song complexity shown by bowhead whales in the Barents Sea is a unique feature of this population, or whether it is a normal trait for bowhead whales as a species.

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A bowhead whale just beneath the surface in the drifting pack-ice in western Fram Strait. Photo: Kit Kovacs and Christian Lydersen / Norwegian Polar Institute

Number of new songs by month and the cumulative number of songs sung in each of three years by bowhead whales in the Fram Strait. Colours represent the three different years of PAM records explored in this study.

FURTHER READING: Stafford KM, Lydersen C, Wiig Ø, Kovacs KM (2018) Extreme diversity in the songs of Spitsbergen’s bowhead whales. Biology Letters 14: 20180056, https://doi. org/10.1098/rsbl.2018.0056 Recordings of bowhead whale songs from this study can be heard at Dryad Digital Library https://doi.org/10.5061/dryad.1ck400f. A sound clip is also available on YouTube: www.youtube.com/watch?v=DyVWOlLJCu4

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Scientists sampling the first data and material for the Nansen Legacy with RV Kronprins Haakon, August 2018. Photo: PĂĽl Ellingsen / University Centre in Svalbard / Nansen Legacy

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Marit Reigstad // UiT The Arctic University of Norway Tor Eldevik // University of Bergen/Bjerknes Centre for Climate Research Sebastian Gerland // Norwegian Polar Institute

The Nansen Legacy Fridtjof Nansen set out to explore the Arctic Ocean with the research vessel Fram 126 years ago. His team of explorers and scientists returned from the ice three years later with new knowledge that changed our concepts and understanding of the Arctic Ocean, and made the Arctic part of Norwegian identity.

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oday, the Arctic that nansen explored is in many ways gone. The retreating Arctic sea ice is an unmistakeable indicator of a changing climate. Satellite observations document and visualise how sea ice is shrinking and thinning, how it begins melting earlier in spring and how autumn freeze-up is delayed. The northern Barents Sea and adjacent Arctic stand out as a region where change is omnipresent in the physical environment, and responses in living Barents Sea ecosystems have already been observed. A rapidly changing Arctic prompts research questions of tremendous intellectual, empirical and logistical complexity, with direct implications for management of Norway’s marine resources and international obligations. All this change calls for a new form of scientific collaboration and commitment.

A DIFFERENT RESEARCH PROJECT New knowledge about this new Arctic is urgently needed. From a vision of increased collaboration conceived by the Norwegian Academy of Sciences and Letters in 2011, grew the ambition of a major national Arctic research effort. The project – the Nansen ­Legacy – has just started its six-year scientific journey to reveal the secrets of the new emerging Arctic. Since the project’s dimensions and ambitions went far beyond any existing funding scheme, a new funding framework and structure had to be developed. This was done in close collaboration between the Norwegian Ministry of Education and Research, the Research Council of Norway, and the institutions involved. A cornerstone is to optimise use of available infrastructure and focus governmental basic funding towards a common scientific goal. The project also contributes towards educating a new generation of polar researchers, and benefits from the timely arrival of RV Kronprins Haakon, Norway’s new ice-breaking research vessel.

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A NEW ARCTIC FUNCTIONS DIFFERENTLY The Arctic has changed substantially in recent decades. Changes in temperature, sea ice, water masses, habitats, and ecosystem processes are pronounced in the marine environment. Processes leading to the changes are interconnected, some in complex ways involving feedbacks and non-linearity. A key challenge is that the “new Arctic” functions differently from the Arctic we used to deal with. As an example, Arctic sea ice has generally become much younger. First-year sea ice differs from older ice types in terms of energy fluxes, mechanical properties and habitat functions. This illustrates that change in one component can affect the Arctic system in general.

The Nansen Legacy research foci centred around the living Barents Sea. Illustration: Rudi Caeyers / UiT The

Despite a recent increase of direct observations in the Arctic, there are still large gaps in time and space. For example, the Arctic winter – the polar night – remains largely unexplored. There is a general and urgent need to link observations – and scientific disciplines – between the physical and biological environments, seasons and regions, and to develop common tools to explore cause and effect.

Arctic University of Norway / Nansen Legacy

WHY THE NORTHERN BARENTS SEA? The increasing area of open waters in the northern Barents Sea literally opens the Arctic to newcomers. These include sub-Arctic fish species like cod and haddock, invasive species like the snow crab, and the fisheries that they attract. Cargo vessels have successfully tested routes across the Arctic Ocean, and there is still a drive to extend petroleum activities further north. It is important that future use of this region be based on a management strategy that is informed by robust knowledge about the ecosystem and the impact of human activities. Norway has a history of sustainable and knowledge-based management in the southwestern Barents Sea. Such a level of knowledge of environmental conditions and changes should also be established in the north. We specifically need to understand how the atmosphere, sea ice, and ocean currents and the ecosystem interact and respond.

The first Nansen Legacy joint cruise with RV Kronprins Haakon took place in the northern Barents Sea in August 2018, a summer when the sea ice edge and marginal ice zone were located relatively far north. The cruise track is in light blue; stations are marked in pink. The background image consists of a mosaic of SAR satellite images from Sentinel-1 (source: ESA) for 15 and 16 August 2018, and the winter sea ice edge for the same year (16 April 2018) from passive microwave satellite data (source: NSIDC, Boulder, USA). Figure credits: Anders Skoglund and Mikhail Itkin / Norwegian Polar Institute

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THE WAY TO INCREASED UNDERSTANDING The living Barents Sea is at the heart of the Nansen Legacy. To understand an ecosystem and its dynamics, it is crucial to have knowledge on the biological communities and the food webs, the interactions between organisms, their growth rates and productivity. Organisms also depend on their physical and chemical environments – which are now changing in many ways. A major challenge is therefore to understand how multiple stressors like increased temperature, acidification and contaminants together impact organisms, and how a longer ice-free season or new food items alter the food web and impact the living Barents Sea. New technology, such as autonomous vehicles, can help us observe habitats in detail under the ice, cover larger regions and provide synoptic measurements, thus improving our observational capability and data quality. ZOOMING IN AND SCOPING OUT Following the retreating sea ice poleward is fundamentally about being able to zoom in and scope out at the same time: to see what happens locally in the present hotspot of the Barents Sea, and relate this coherently to present and future environmental change, within the Arctic and beyond. The Nansen Legacy will: 1) observe, in the field, what largely has not been observed before; 2) relate a living Barents Sea in flux to the incomplete Arctic “ground truth” that can be determined from present knowledge; and 3) estimate present and future climate and ecosystem states using theory, computer models, and statistical considerations.

The Nansen Legacy aims to understand how the climate and ecosystem function by investigating variability in the past, and resolving processes and interactions in the present, to project future scenarios. Illustration: Tor Eldevik / University of Bergen, Bjerknes Centre / Nansen Legacy

Models, when adequate, link and synthesise incomplete observations in space and time through modelled cause-and-effect. The observational basis – the information collected in the real world – informs models and contributes to their improvement; models place incomplete observations in a consistent context. Examples during the first year of the Nansen Legacy include: the improvement of weather forecasting by better consideration of the actual state of the sea ice cover; the statistical prediction of Barents Sea cod stock into the 2020s from the presently observed state of the ocean; and reconstruction of sea ice and ocean climate states from sediment cores at the ocean floor, revealing changes over the last 10 000 years.

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THE LEGACY In the spirit of Fridtjof Nansen, who set out to understand the Arctic Ocean and how it connects across the Arctic and to lower latitudes, the Nansen Legacy will contribute extensive new knowledge to scope out, integrate and connect the Barents Sea and adjacent Arctic Ocean to the entire Arctic. The new data, observational systems, improved models and future scenar-

ios on the new Arctic the project provides will enable future sustainable management. The Nansen Legacy exemplifies how innovative research and science organisation can address knowledge gaps and foster a new generation of polar researchers – trained across disciplines, institutions and nations – providing the competence we need to handle the new Arctic future.

Nansen Legacy The Nansen Legacy is a collaborative project between ten Norwegian research institutions with Arctic marine expertise, and with competence and perspectives including education, management and contact with different user groups. Project period: 2018-2023 Budget: 740 million NOK Funding: 50% in-kind from involved institutions, 25% from the Research Council of Norway, 25% from the Norwegian Ministry of Education and Research Research group: More than 130 scientists from the involved institutions, about 50 recruitment positions (PhD and post docs), associated members, international collaborators Website: http://www.nansenlegacy.org

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Angelika HH Renner and Sigrid Lind // Institute of Marine Research Arild Sundfjord // Norwegian Polar Institute

Warm water, fresh water, wind and tides – ice or no ice around Svalbard? September onboard the research vessel Lance north of Svalbard. Kristen, our mooring engineer, is happy. There is no sea ice to be seen anywhere – ideal conditions to find the instruments we left here two years ago attached to a rope, anchored to the seafloor, and held upright under water by several buoys.

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ithout ice, lance is free to move around and locate the mooring using the ship’s echo sounder. Kristen sends the command to the mooring to let go of the anchor, and the rest of us scan the water surface. Luckily, the buoys are easy to spot when they come up. The crew lifts everything onto the deck, and a little later, we have two years of temperature, salinity and current data in our hands. They will help us understand how the ocean is changing around Svalbard. In recent years it has become increasingly normal that the ocean around Svalbard is free of sea ice. While this is good news for ship traffic, fisheries, and potential other exploitation of resources around Svalbard, a shift towards an ice-free normal can also be seen as an alarming sign of drastic changes in the climate system.

Svalbard is at the front between the Arctic and Atlantic domains. This is the entrance to the Arctic Ocean where large amounts of heat are brought in with the Atlantic Water current – a continuation of the Gulf Stream flowing northward along the Norwegian coast and around Svalbard. When Atlantic Water enters the Arctic, it encounters fresher Arctic waters. Since the Atlantic Water contains more salt and is denser, it becomes submerged and continues into the Arctic Ocean below the Arctic Water. This means that the Arctic Ocean is stratified, with a cold and fresh Arctic layer above a warm and saline Atlantic layer. The Arctic layer thus restricts the amount of heat that comes up from below, enabling sea ice to form and persist in cold winter conditions.

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The A-TWAIN cruise, September 2017, did eventually find some sea ice… Photo: Angelika Renner / Institute of Marine Research

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But these patterns are changing. New research at the Fram Centre reveals an altered inflow of warm water and ongoing changes to the stratification (i.e. the gradient between fresher surface layers and more saline Atlantic Water), and emphasises how these changes play a key role in enhanced warming and reduced sea ice cover in this region. North of Svalbard, Atlantic Water is carried by a narrow current along the continental slope and is pushed below a layer of Arctic Water as it travels eastwards. In recent years, the Atlantic Water has been able to continue at the surface further east than before throughout much of winter. The Fram Centre “Arctic Ocean” Flagship project A-TWAIN has been monitoring the Atlantic Water boundary current since 2012 using an array of moored instruments north of Kvitøya. Results from this project show how the heat in this boundary current, in combination with wind-driven mixing and tides, has contributed to keeping the region free from sea ice until the middle of winter, when sea ice appears and a cold and fresh meltwater layer is established. This thin layer of cold water, which can be formed locally by sea ice melt or can be moved in from the north by wind, protects the sea ice cover from the Atlantic Water heat below.

Instruments waiting on the deck of RV Lance, ready to be deployed again north of Svalbard.

The largest inflow of warm water from the North Atlantic occurs in autumn and early winter. During this time of the year, large pulses of water with temperatures of up to 5°C arrive at the continental slope north of Svalbard. With longer periods of open water, wind will mix the upper part of the water column more efficiently, and the surface will not freeze despite very low air temperatures and the sun being below the horizon. It is only when the temperature and volume of incoming warm water decrease later in winter, and the surface becomes sufficiently cold and fresh, that sea ice forms locally, or that sea ice blown into the region from the north, can persist and not be melted by the Atlantic heat.

Photo: Angelika Renner/ Institute of Marine Research

Behind the front in the northern Barents Sea, the layer of fresher Arctic waters is thicker and more persistent than north of Svalbard: winter-cooled water with temperatures down to freezing-point occupies the upper 100 m of the ocean. Here, the “Arctic layer” persists and remains cold through the summer, thereby making the conditions ready for sea ice growth earlier in autumn and winter.

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Spring / Early summer Solar Radiation

Wind-driven mixing SEA ICE

Cold freshwater from melt ATLANTIC WATER

Heat transport

Tid e CONTINENTAL SHELF

-dr ive nm ixin g

Illustration: Reibo / Arild Sundfjord, Norwegian Polar Institute and Angelika Renner, Institute of Marine Research

Autumn / Early winter

Wind-driven mixing

Cold freshwater from melt

SEA ICE

ATLANTIC WATER

Heat transport

Tid e CONTINENTAL SHELF

-dr ive nm ixin g

Illustration: Reibo / Arild Sundfjord, Norwegian Polar Institute and Angelika Renner, Institute of Marine Research

Illustrations: Reibo / Arild Sundfjord, Norwegian Polar Institute and Angelika Renner, Institute of Marine Research

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Illustration: Reibo / Sigrid Lind, Institute of Marine Research

The Institute of Marine Research together with its Russian partner, PINRO, have been monitoring the marine environment in the Barents Sea in late summer since 1970. A new study using this extensive set of observations of ocean temperature and salinity shows that vertical mixing between the Arctic and Atlantic layers brings up heat and salt. The salt flux means that a freshwater input is needed to sustain the freshwater reservoir and stratification. Using satellite data in combination with the hydrographic data, the study shows that sea ice import into the Barents Sea is the most important freshwater source.

part of the Atlantic domain, where Atlantic Water occupies the entire water column.

Recently, a decline in sea ice import and freshwater input has led to a major loss of freshwater, weakened ocean stratification and facilitated efficient vertical mixing between the layers, resulting in an extreme warming of the Arctic layer. This heat is then released to the atmosphere in winter. This contributes to the development of the Barents Sea as a hotspot of Arctic warming, with the highest rates of atmospheric temperature rise and winter sea ice decline in the Arctic. Unless the freshwater input recovers, the stratification can break down and the entire region could become

As climate change is leading to a strong warming in the Arctic, both in the ocean and in the atmosphere, and to a drastic decline in sea ice extent in all seasons, less sea ice is transported into the northern Barents Sea, and local freshwater volume decreases. This in turn allows the upper ocean to warm dramatically from below, contributing to the fastest temperature increase and greatest winter sea ice decline yet observed in the Arctic. North of Svalbard, the sea ice is thinning and melting faster than before, enabling the Atlantic Water to stay at the surface further east than

The fresh surface layer in the northern Barents Sea is maintained by melting sea ice imported from the Arctic Ocean, and is thus thicker during summer when more ice melts. The sea ice cover and the freshwater layer support each other’s presence. North of Svalbard, both sea ice and the surface freshwater layer are strongly influenced by wind, and fresh water is brought in both through sea ice melt and by advection from further north and east in the central Arctic.

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Atlantic Water flows into the Arctic with the continuation of the Gulf Stream and splits into several smaller currents. The star indicates where the

NORWAY

A-TWAIN array is moored north

RUSSIA

of Kvitøya. Illustration: Reibo / Arild Sundfjord, Norwegian Polar Institute

ICELAND

and Angelika Renner, Institute of Marine Research Illustration: Reibo / Arild Sundfjord, Norwegian Polar Institute and Angelika Renner, Institute of Marine Research

it used to. Prolonged ice-free periods will enable more direct influence of the wind on mixing in the ocean. At the same time, the efficiency of tides in redistributing heat might change as stratification weakens. It will be important to follow this region closely in the coming years. The A-TWAIN mooring array north of Svalbard is continuing to record the properties of the inflowing Atlantic Water boundary current, and new projects will help extend the array. Later in 2019, Kristen will be back at sea to search for the moorings, recover the instruments, and put out new moorings so that we can slowly build up a longer time series also in this region. The annual monitoring of the Barents Sea by IMR and PINRO continues and is being extended with the new icebreaker RV Kronprins Haakon. The Nansen Legacy project (see article on page 100) expands the interdisciplinary research, enabling us to include more chemical and biological parameters in our work, and to further investigate linkages between the northern Barents Sea and the region north of Svalbard, the entrance to the Arctic. With the observed rapid climate change, will larger parts of the Eurasian Arctic shift towards an Atlantic climate?

Will a new frontier region develop further east in the Arctic? How will the ongoing changes affect societies and ecosystems around Svalbard, the Barents Sea and the Norwegian mainland? The Fram Centre with its partner institutions and key projects are in a very good position to take a lead in understanding how our region will develop in the near future.

FURTHER READING: Renner AHH, Sundfjord A, Janout MA, Ingvaldsen RB, Beszczynska-Möller A, Pickart RS, Pérez-Hernández MD (2018) Variability and redistribution of heat in the Atlantic Water boundary current north of Svalbard. Journal of Geophysical Research 123(9): 6373-6391, doi:10.1029/2018JC013814 Lind S, Ingvaldsen RB, Furevik T (2018) Arctic warming hotspot in the northern Barents Sea linked to declining sea-ice import. Nature Climate Change 8: 634-639, doi:10.1038/s41558-018-0205-y

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One of the seals instrumented in Kongsfjorden in 2012 returns to the water with the sensor attached. Photo: Kit Kovacs and Christian Lydersen / Norwegian Polar Institute

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Alistair Everett, Jack Kohler, Arild Sundfjord, Kit M Kovacs and Christian Lydersen // Norwegian Polar Institute

Where seals dare Glacier fronts along Svalbard’s coast are dangerous places. Huge blocks of ice detach and crash into the ocean below, making data collection all but impossible. Now, researchers have found a solution: attaching sensors to ringed seals that dare to go where humans cannot. Seals make brave research assistants!

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n 2012, researchers from the Norwegian Polar Institute attached biotelemetry devices to ringed seals (Pusa hispida) in Kongsfjorden, on the west coast of Spitsbergen. The devices collected a vast array of information about the seals’ behaviour, including their location, time spent in and out of the water, and dive information. In addition, the devices measured the temperature and salinity of the water masses through which the seals swam. Six years on, this exciting dataset is still providing valuable new insights into the seals’ behaviour and the ocean properties in areas that have previously been difficult to access. Kongsfjorden is a large Arctic fjord on the northwest coast of Spitsbergen, the main island in the Svalbard archipelago. Several large glaciers terminate in the ocean in Kongsfjorden, the largest and deepest of which is the shared Kronebreen–Kongsvegen glacier

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terminus. The terminus is around 3.5 km wide and extends up to 90 m below the ocean surface to the sea floor below. A common feature at the terminus of Kronebreen are muddy-red plumes of sediment that emerge immediately in front of the glacier. The plumes are formed by glacial meltwater flowing underneath the glacier, eroding the iron-rich Old Red Sandstone beneath the glacier, and emerging into the ocean tens of metres below the surface. When the meltwater emerges, it is cold, fresh and buoyant compared to the salty, more dense water in the surrounding ocean. The plume therefore rises rapidly, hugging the glacier front, until it reaches the surface. WHY ARE PLUMES IMPORTANT? Plumes are a common phenomenon at ocean-terminating glaciers around Svalbard and elsewhere in the Arctic, and have recently attracted the attention of researchers from a number of different disciplines. For glaciologists, plumes have an important effect on the glacier terminus. The rapidly rising water draws in the surrounding warmer ocean water toward the front of the glacier, dramatically increasing the submarine melt rate and cutting deep notches into the ice. Oceanographers are interested in the large volumes of deep water that plumes can carry up to the surface, driving complex circulation patterns and mixing within the fjord. Biologists have observed that seabirds, such as black-legged kittiwakes (Rissa tridactyla) and northern fulmars (Fulmarus glacialis), appear to use the area where the plume reaches the ocean surface as an important feeding ground. But, so far, what goes on below the ocean surface has been difficult for scientists from all disciplines to observe. Analysis of the temperature and salinity data collected by the ringed seals in Kongsfjorden has now opened up a new window into this hidden world. WHAT DATA DID THE SEALS COLLECT? Previous research has shown that ringed seals, and other marine mammals such as white whales (Delphinapterus leucas), spend a lot of time foraging close to glacier termini. But the temperature and salinity profiles collected in 2012 contained a new and interesting

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Kittiwakes, fulmars and ringed seals are often seen feeding at the terminus of Kronebreen glacier. Huge blocks of ice frequently detach and crash into the water below. Scientists must keep a safe distance, but ringed seals like the one in the centre of this photo are a little more bold. Photo: Kit Kovacs and Christian Lydersen / Norwegian Polar Institute

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feature which shed light on exactly what was attracting animals to the glaciers. In amongst the many typical oceanographic profiles were profiles containing large “spikes” of water with low temperature and low salinity, often more than forty metres below the ocean surface. These “spikes” are a sign of instability in the water column due to the low salinity water in the “spike” being less dense than the saltier water above. This suggested that the water sampled in the “spikes” must be moving upwards through the water column, thus providing the first evidence that the seals had entered the plumes. The second indication came from the location data. Whereas previous devices relied on the Argos satellite system, with an accuracy of less than 150 m, the instruments used on the seals in 2012 included GPS devices, allowing the seals’ dives to be located within a few metres. This permitted a more detailed analysis of the seals’ dive locations close to the terminus. Using these dive locations with a clustering algorithm, which can identify where and when the seals were diving in the same location, we found that the seals were diving in specific locations along the glacier terminus. These locations closely matched known locations of subglacial discharge.

Measurements of salinity while the seals were diving. Each line is a different dive. Note the very low salinities found between 40 and 80 m depth.

The sensor is glued to the seal’s fur and will fall off next time the animal moults. Photo: Kit Kovacs and Christian Lydersen / Norwegian Polar Institute

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Locations of the seals’ dives. The main image shows the density of the seals’ dives close to the glacier terminus. Yellow colouring shows more than fourteen profiles collected in that location, decreasing to two dives in dark blue areas. Areas that are not coloured have two or fewer dives. The location of the plume is visible in the inset satellite images.

WHAT CAN WE LEARN FROM THE DATA?

WHAT DOES THE FUTURE HOLD?

Analysis of the temperature and salinity properties in the “spikes” showed that the seals collected data consistent with concentrations of 27% subglacial discharge at sixty metres beneath the ocean surface. Previous studies found it very difficult to collect samples from deeper than 20 metres within the plumes due to the vigorous upwelling, and the highest concentrations of subglacial discharge were between 2 and 10%. This new technique will help us to compare modelling studies of plumes to the real world and improve estimates of melting and upwelling driven by the plume.

Increased surface melt and glacier runoff may initially strengthen and prolong plumes at the glacier terminus during the melt season. However, while this may temporarily lead to an increase in the availability of food for top predators, it will also hasten the glacier’s retreat. As Kronebreen retreats, it will move into progressively shallower water until it eventually becomes land-terminating; when that happens, this important foraging area will be lost.

The long time series of location data show that the seals moved quickly between plumes in different locations at the glacier terminus, and that peaks in meltwater runoff from the glacier coincided with periods during which the seals clustered closely together. This demonstrates that the plumes play an important role in the ecosystem close to the glacier, but also suggests that outlets of subglacial discharge may change their position along the terminus quickly, providing new insight into the dynamics of the subglacial hydrology.

FURTHER READING: Everett A, Kohler J, Sundfjord A, Kovacs KM, Torsvik T, Pramanik A, Boehme L, Lydersen C (2018) Subglacial discharge plume behaviour revealed by CTDinstrumented ringed seals. Nature: Scientific Reports https://doi.org/10.1038/s41598-018-31875-8

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Halfdan H Helgason, Hallvard Strøm, Sébastien Descamps and Benjamin Merkel // Norwegian Polar Institute Børge Moe, Vegard Bråthen, Arnaud Tarroux and Per Fauchald // Norwegian Institute for Nature Research Morten Ekker // Norwegian Environment Agency

Large-scale seabird movements throughout the year – SEATRACK 2014-2018 The large-scale seabird tracking programme SEATRACK has finished its first five-year phase. The project has improved and expanded what we know of the behaviour and distribution of Northeast Atlantic seabirds. One key finding is that the Barents Sea is far more important in winter than previously known.

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eatrack was formally initiated in spring 2014. The aim of the project was to map where seabirds that breed in colonies encircling the Barents, Norwegian and North Seas are during the non-breeding season. This would allow us to predict how changes in environmental conditions in wintering areas might affect seabird demography and population trends. As long as we were unable to determine the movements of individuals from different breeding populations, our understanding of seabird distribution and the potential causes and consequences of different migration strategies was severely limited.

The advent of global location sensing technology at last gave us the tools we needed to link breeding populations to their non-breeding habitats, knowledge that is essential for marine spatial planning and seabird conservation. SEATRACK has also given us a range of invaluable tools for population management and seabird research. Seabirds migrate and gather in colonies with no regard to national borders or jurisdictions. Consequently, the responsibility for the conservation and management of seabirds is shared among several nations.

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The Barents Sea is far more important for wintering

populations’ wintering grounds. Yellow represents data

seabirds than we previously knew. This map shows the

from populations where no such studies had previously

winter distribution (Nov-Feb) of Brünnich’s guillemots

taken place and whose wintering grounds were unknown.

as density kernels. Red represents data from colonies

Red dots mark previously established tagging sites and

included in SEATRACK where geolocator studies had been

yellow dots newly tagged colonies.

established and we already knew something about the

An estimated 26 million pairs of seabirds breed in colonies along the coast of the Northeast Atlantic and the European Arctic, and many species are in severe long-term population declines. In order to predict potential threats and assess a species’ resilience, we need a good understanding of wintering and staging areas and how the birds use them, which migratory routes they follow, and how populations spread and mix. This was the thinking behind SEATRACK, a coordinated multi-year, multi-site and multi-species seabird

tracking effort. The project spanned 38 colonies in five countries. Individuals of 11 seabird species were tagged with small, lightweight archival tags, called geolocators. Each individual’s position can be calculated twice daily using the ambient light levels recorded by the tag, in relation to time of day. Since the tags are archival, they must be physically recovered to obtain data, and recapturing each tagged individual is an interesting challenge. However, the novelty of the project lies not in the technology used, but in the large scale and synchronicity of the deployment efforts, and the standardised methodology.

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For example, new map products are being developed to show habitat and abundance. The first version of the abundance maps for six of the study species was introduced in October 2018. These maps constitute a new and extremely useful tool for population management and marine spatial planning and will likely prove invaluable both in conservation efforts and in responses to acute threats such as oil spills. The SEATRACK web application will soon also include abundance maps.

Seabird colonies where loggers have been deployed on behalf of SEATRACK 2014-2018.

Over the last five years, more than 10 500 geolocators have been deployed and so far over 4 400 have been retrieved, shedding light on individuals’ locations throughout the year. In early 2018, the project database held around 1.6 million raw positions comprising 3 363 annual tracks from 2 130 individuals. Data gleaned from 1 214 loggers retrieved in 2018 have yet to be processed into the database and will likely yield about 2 000 additional tracks. All data currently available in SEATRACK’s database can be viewed online in a web application http://seatrack.seapop.no/map/ which was launched in March 2017 along with the project’s webpage http://www.seapop.no/en/seatrack. In this freely accessible web application, users can plot and compare the distribution kernels of various species and/or populations in different seasons and years. SEATRACK data can also be combined with environmental data and population sizes and used to predict abundance of seabirds in time and space.

To date, SEATRACK has provided unique insight into details in the life history of different seabird populations, such as timing of migration, migration routes and selection of overwintering areas. New information has come to light while more detailed analyses of the data are still under way. It has become clear that certain geographical areas are crucial to seabird species throughout the winter or for shorter periods in autumn. One of the most important findings so far is that the Barents Sea is much more important as a wintering ground – and important for more seabird populations – than previously thought. It turns out that huge numbers of seabirds spend the winter in the Barents Sea, for example, the large Brünnich’s guillemot populations from the east coast of Spitsbergen and Novaya Zemlya – populations that have never been tracked before. Much work remains, but at the end of 2018, the project had run its course as originally scheduled. To complete that work, address new questions that have arisen, and establish new technological knowhow, we have drawn up plans for a second phase of the project and funding is being sought. The first phase was financed jointly by the Ministry of Climate and Environment, the Ministry of Foreign Affairs and the Norwegian Oil and Gas Association, along with nine corporations in the energy sector (Equinor, Neptune Energy, DEA Norway, Eni Norway, ConocoPhillips, Total, Wintershall, Aker BP and Lundin). The programme is led by the Norwegian Polar Institute in collaboration with the Norwegian Institute for Nature Research and the Norwegian Environment Agency. SEATRACK involves close cooperation with specialists in each partner country, with more than 20 participating institutions contributing to the effort.

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Predicted absolute densities (abundance) of Atlantic puffins breeding in colonies around the Northeast Atlantic in January. The model is based on a range of environmental variables, population sizes and SEATRACK data, weighted to cover over 90% of the Northeast Atlantic population.

A screenshot of the SEATRACK web application (http:// seatrack.seapop.no/map/). The winter distribution of Atlantic puffins Nov 2015 – Jan 2016 is displayed as an example. Different colours allow the user to visually compare the seasonal distributions of the birds from different colonies and species in different years.

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Heidi Ahonen, Christian Lydersen, Laura de Steur and Kit M Kovacs // Norwegian Polar Institute Kathleen M Stafford // University of Washington, USA

Arctic “unicorns” – year-round residents of western Fram Strait Narwhals live in ice-filled waters of the North Atlantic throughout their lives, similar to their more widely dispersed, circumpolar relative the white whale (or beluga whale). Most research on this remarkable High Arctic animal has taken place in the eastern Canadian/West Greenland area.

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atellite-tracking studies have shown that narwhals occupy deep offshore areas in the winter and migrate into coastal areas over the continental shelves in summer. However, in the Barents Sea region we see them only rarely in coastal areas around Svalbard, regardless of the time of year. They are capable of diving for an hour or more to great depths in search of giant squid and bottom-dwelling fish. They are quite shy, and can hear ships at great distances, so they can easily escape detection by leaving the surface for long periods when they choose to “disappear”. ACOUSTIC SPYING To learn more about the Red Listed population of narwhal in the Barents Region, we have been “listening” for them using Passive Acoustic Monitoring (PAM) devices. Recent analyses of several years of PAM records from the western Fram Strait have provided quite amazing results. Narwhal signals were detected year-round (year after year) at a mooring site that sits at the edge of the continental slope east of Greenland (west of Svalbard at about 79°N). Perhaps even more surprising was the fact that the narwhal sounds

occurred more frequently when warm Atlantic Water influxes occurred in the area. We certainly do not have all the answers (yet) to explain these results, but the presence of narwhal throughout the year in western Fram Strait is likely facilitated by the almost constant flow of drifting fields of Arctic ice, carried southward by the East Greenland Current, creating ideal habitat all months of the year. The increase in acoustic signalling when warm water influxes take place might be associated with the formation of frontal areas, which are created when warm currents meet cold currents. Such fronts likely concentrate narwhal prey.

FURTHER READING: Ahonen H, Stafford KM, Lydersen C, de Steur L, Kovacs KM (2019) A multi-year study of narwhal occurrence in the western Fram Strait – detected via passive acoustic monitoring. Polar Research http://dx.doi.org/10.33265/ polar.v38.3468

IN BRIEF

FRAM FORUM 2019

Unicorns of the sea – three male narwhals travelling together

Four narwhals (lower right) moving along the edge of the

in icy waters of the Fram Strait in early fall 2018. Photo: Kit

drifting pack-ice east of Greenland. Photo: Kit Kovacs and

Kovacs and Christian Lydersen / Norwegian Polar Institute

Christian Lydersen / Norwegian Polar Institute

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Spectrogram showing echolocation clicks and pulsed signals of narwhal, recorded in Fram Strait.

Narwhal acoustic signals (hours per day, bottom) in Fram Strait compared to ice cover and distance to the ice edge (top) and % Atlantic Water in the upper 500 m of the water column (middle).

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OUTREACH

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Ann Kristin Balto // Norwegian Polar Institute

Two towers Two towers symbolise the Arctic and the Antarctic when we enter the atrium at the new Fram Centre. The towers are a monumental 13 metres high and 4 metres wide. With frank, open gazes, the portraits of a man and woman welcome visitors to a magnificent room with a glass ceiling. Who were these two people who now show us the way to the north and south poles?

HANNA RESVOLL-HOLMSEN was the first female scientist in Svalbard. She was a botanist who hungered for knowledge about Arctic plants. She was one of several scientists in a team of Norwegian scientists who participated in an expedition funded by Prince Albert of Monaco in 1907. The fieldwork she did piqued her interest, and she returned to Svalbard the following year with a team of geologists: Adolf Hoel, Gunnar Holmsen and Hjalmar Johansen. Armed with her plant press, botanist’s chest, photographic equipment, provisions – and a rifle – she went ashore at several locations along the west coast of Svalbard to explore the plants. The results were published first as a thesis on Arctic plants, and later as a book: Svalbard flora.

Botanist Hanna Resvoll-Holmsen graces the western tower in the atrium at the Fram Centre. This picture was taken during a book café. Photo: Ann Kristin Balto / Norwegian Polar Institute

Hanna was a pioneer. She laid the foundation for systematic mapping of Svalbard’s flora. She was the first person to take colour photographs of Svalbard. She participated in the efforts to bring Svalbard under Norwegian sovereignty, and she fought to protect natural areas in mainland Norway and Svalbard.

FRAM FORUM 2019

OUTREACH

Per Savio and Ole Must participated in Carsten Borchgrevink’s expedition to Antarctica 1898-1900. Photo: Ellisif Wessel / Norwegian Polar Institute

A monumental portrait of Per Savio greets visitors as they enter the atrium. Photo: Malin Alette Hansen / Norwegian Polar Institute

PER SAVIO was a young man when he left his Sápmi home and headed out on the adventure of a lifetime. He would go as far from home as was physically possible: to the Antarctic. Per Savio was accustomed to cold climates. Growing up in Sør-Varanger in Finnmark, he had to know how to dress in the bitter cold. He knew how to sew warm leather garments and skaller (boots made from reindeer fur by the Sámi people). He was well acquainted with snow, weather and wind;

he knew how to travel in extreme weather and in the polar night – and he was an expert dog musher. This expertise was useful when he tended the dogs for the British Antarctic Expedition of 1898-1900 and the team overwintered at Cape Adare. It was a hard winter, and lives were lost, but expedition leader Carsten Borchgrevink later wrote that things could have gone a lot worse without the SNOWHOW of the Sámi men.

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Hjalmar Johansen, Hanna Resvoll (later Resvoll-Holmsen) and Gunnar Holmsen on board the expedition vessel

ANNE-KARIN FURUNES is a contemporary Norwegian artist known for her monumental portraits, created through a process of perforating the surface of metal sheets. This technique results in haunting, confrontational images. She was born on 26 May 1961 in Ă˜rland, Norway, and studied at the Royal Danish Academy of Fine Arts in Copenhagen from 1983 to 1984, and at the National Academy in Oslo from 1986 to 1991. Furunes is currently a professor at the Trondheim Academy of Fine Art in Trondheim, Norway. The works at the Fram Centre are part of the collection Art in Public Spaces (KORO); Claes Sødergren was project manager. Photo: Ann Kristin Balto / Norwegian Polar Institute

Holmengraa in 1908. Photo: Norwegian Polar Institute

Hanna Resvoll-Holmsen and Per Savio represent the north and the south. They are overshadowed by the great polar heroes, but their work was central in advancing their respective fields. Resvoll-Holmsen was a groundbreaker in her scientific discipline, and a pioneer among women, while Savio and others like him provided crucial support to Norwegian polar heroes. Without their assistance, the big names among polar explorers might never have returned from their expeditions over a century ago. The quest for knowledge and the work done by Hanna Resvoll-Holmsen and Per Savio continues today, supported by the Fram Centre. Scientists would not survive expeditions to inhospitable areas without help from experienced people who know their logistics. The Fram Centre supports extensive collaborations across various fields, disciplines and institutions. Broad collaboration is the way to go in our quest for more knowledge.

FRAM FORUM 2019

Per Savio was in charge of the dogs during Borchgrevink’s expedition to Antarctica. Savio used skis to get around. Photo: Norwegian Polar Institute

The towers in the Fram Centre atrium are decorated on several sides and can be admired from the stairways and the gangways between the buildings. The tower that symbolises Antarctica features images of Per Savio and his dogs, and Sámi words for snow. Hanna Resvoll-Holmsen’s botanical drawings and the plants’ latin names adorn the tower that represents the Arctic. Photos: Ann Kristin Balto / Norwegian Polar Institute

OUTREACH

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RESEARCH NOTES

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Synnøve Elvevold and Per Inge Myhre // Norwegian Polar Institute Ane K Engvik // Geological Survey of Norway Joachim Jacobs // University of Bergen

Geological mapping of Norway’s least explored mountains Four geologists participated last winter in the Norwegian Polar Institute’s expedition to Norway’s Troll research station in central Dronning Maud Land, Antarctica. The main goal of the expedition was geological mapping of the region’s nunataks – mountain peaks completely surrounded by glacier ice.

Homogenous, resistant lithologies like syenite and monzonite often form nearly vertical mountainsides. Hoggestabben is an impressive mountain with 900 m high, steep cliffs. Photo: Synnøve Elvevold / Norwegian Polar Institute

FRAM FORUM 2019

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he mountain range of dronning maud land is an exposed row of nunataks that runs roughly parallel to the edge of the East Antarctica ice sheet, about 200 km inland. The barren nunataks of Fimbulheimen are Norway’s least explored mountains, and probably the most spectacular. The steep rock faces lack vegetation and are polished by the ice. The excellent quality of the exposures provides a unique opportunity to study the various geological processes that have affected and formed the bedrock in Dronning Maud Land. The purpose of the 2017-2018 expedition was to produce a new geological map of the area surrounding the Norwegian Troll station in central Dronning Maud Land. Mapping and thematic surveys in a claimed territory are considered a fundamental obligation for the claiming country. It is thus important to follow up geoscientific activities in Antarctica by taking an active role in geological mapping and research.

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Geological maps communicate vast amounts of geological information. The maps show the distribution of different geological features, including rock types and structural features such as faults, folds and foliations. The maps also contain information about the relative age of the rocks, as well as the relative order of geological events such as deformation, metamorphism, intrusion of magma, erosion, and many others. Geological mapping is an interpretive, scientific process and involves several disciplines including petrology, geochemistry, structural geology, geochronology and stratigraphy. The new results from the expedition will increase our knowledge on the geology of Dronning Maud Land, and will thus be an important contribution to management-related research and mapping in the Norwegian polar regions.

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The massive cliff is composed of grey migmatitic gneiss and is intruded by three generations of dikes. The black dike is deformed, whereas the white pegmatitic dike and the horizontal brownish dike cross-cut all structures. Photo: Synnøve Elvevold / Norwegian Polar Institute

RECONSTRUCTING ANCIENT SUPERCONTINENTS During the Precambrian period, most or all of the earth’s continental blocks assembled as “supercontinents”, then dispersed again. This happened several times. The formation of large continental masses by plate collision has resulted in major mountain ranges and high erosion rates, and each supercontinent has marked the start of significant global climate change. The bedrock of Dronning Maud Land has a long and complex geological evolution, and preserves evidence of being part of two supercontinent configurations: Rodinia and Gondwana. The oldest rocks in the area formed about 1100-1200 million years ago during the assembly of Rodinia. In the area around Troll, these rocks are present as migmatites and granitoid gneisses. The older (Precambrian) gneisses underwent a new episode of orogeny (mountain-building) during the assembly of the supercontinent Gondwana 500600 million years ago. Various continental blocks were assembled in Gondwana along a network of mountain ranges that are known as the Pan-African mountain belt. The mountain range that went through East Africa and Dronning Maud Land was probably one of the largest orogens1 on Earth, and has been compared to today’s Himalayas.

The geology team. Left to right Joachim Jacobs from the University of Bergen, Synnøve Elvevold from the Norwegian Polar Institute, Ane K Engvik from the Geological Survey of Norway and Per Inge Myhre from the Norwe-

During this period, the bedrock of Dronning Maud Land underwent deformation, high-temperature transformation (metamorphism), partial melting and formation of new crust. Thermodynamic modelling of equilibrium phase diagrams, based on observed mineral assemblages and geochemical analyses, demonstrate that metamorphism of the gneisses took place at temperatures between 750-850°C and at pressures corresponding to crustal depths of about 25-30 km. In other words, the high-temperature crust exposed at the surface today in Dronning Maud Land reveals a

gian Polar Institute. Photo: Christina Pedersen / Norwegian Polar Institute

1

An orogen develops when a continental plate crumples and is pushed upward to form one or more mountain ranges.

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Norway in Antarctica

The nunataks of Hochlinfjella consist of granite that

Dronning Maud Land comprises nearly one sixth of the Antarctic continent, and is seven times larger than Norway. This part of Antarctica was annexed by Norway in January 1939, and is now one of Norway’s three dependencies in the southern hemisphere. Read more about the annexation here: http://polarhistorie.no/artikler/2008/ annekteringen%20av%20dronning%20 maud%20land [Article in Norwegian]

intruded during a late stage of the Pan-African orogeny. Note the dark weathering colour. Photo: Joachim Jacobs / University of Bergen

deeply eroded section through the central part of the 500-600 million year old Pan-African orogen. Large volumes of granitoid magmas intruded the gneisses at a later stage of the Pan-African orogeny. The magma crystallised to form new rocks such as granite, charnockite, syenite and monzonite. These magmatic intrusions are massive and often form the spectacular, jagged peaks and alpine ranges that are so characteristic of the landscape in central part of Dronning Maud Land. Another distinctive feature of the granitoid rocks is the dark-brown weathering colour, which often makes them recognisable at a great distance. Towards the end of the Pan-African mountain-building event, the thickened crust became unstable. Extension of the crust in Dronning Maud Land caused rocks from deeper crustal levels to be carried to more shallow levels. The extension (stretching) continually occurred from crustal depths where ductile (plastic) deformation of the rock mass takes place, towards higher crustal levels where the rocks deform in a brittle fashion. Structures formed at the different crustal levels can be observed as folds, shear zones and faults.

Since 1959, the entire Antarctic, including Dronning Maud Land, is managed under the Antarctic Treaty. The Norwegian Polar Institute has managing authority for all Norwegian activity in the Antarctic, and is also the national mapping authority in Dronning Maud Land. Dronning Maud Land is home to Norway’s Troll research station, which is located in Jutulsessen, 1275 metres above sea level at 72°S. The Norwegian Polar Institute also operates Troll Airfield which is a 3000 m long airfield on blue ice, a few kilometres from Troll station.

Gondwana began to break up 180 million years ago. The different crustal fragments drifted apart, and most of the continents, subcontinents and islands we now recognise, like Africa, India and Madagascar, began to drift north towards their present location. Today, Antarctica lies isolated around the South Pole. The geographical isolation led to climatic cooling and ultimately to glaciation of the southernmost continent on Earth.

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IN BRIEF

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Kenichi Matsuoka, Anders Skoglund, George Roth, Yngve Melvær and Stein Tronstad // Norwegian Polar Institute

Quantarctica 3 released The Antarctic Ice Sheet is huge, roughly 4000 km by 5000 km, about 43 times larger than mainland Norway. Antarctica’s interconnected ocean, atmosphere, lithosphere, and cryosphere host myriad food chains from plankton to top predators. To help the Antarctic community keep track of it all, we created Quantarctica.

V

ersion 3 of the open GIS package “­Quantarctica” was released in 2018. This geospatial data package is built on the free, open-source, cross-platform QGIS software. It is capable of operating entirely offline (for example during Antarctic field work or a cruise in the Southern Ocean), and includes a wide range of cartographic basemap layers, scientific data sets, and satellite imagery. Quantarctica was first released in 2013. A year later, the Scientific Committee on Antarctic Research (SCAR) designated it as an official SCAR product. Before version 3 in 2018, Quantarctica’s main users were glaciologists, because the package included only the base map, satellite imagery, and glaciological data.

the project’s extent and data coverage to 40°S, so that Quantarctica is now not just for Antarctic scientists but for sub-Antarctic and Southern Ocean scientists as well.

In 2014, we were fortunate to receive two-year project funding from the Ministry of Foreign Affairs to expand the data coverage and enhance the user-oriented aspects, thus making Quantarctica suitable for a larger user community. To ensure that we collected the most high-quality, useful, and state-of-the-art data from a wide range of disciplines, we formed the Quantarctica editorial board. The board selected more than 150 peer-reviewed data sets covering glaciology, geophysics, atmospheric science, biology, oceanography, social sciences, and more. We also expanded

Quantarctica starts with both simple and detailed basemaps. Many features in the detailed basemap are scale-dependent, so you can zoom to the appropriate level of detail depending on your area of interest. We have three sets of satellite data (Landsat, Radarsat, and MODIS) for the entire continent and for the sub-Antarctic islands, with pixel sizes ranging from 15-125 m.

Indeed, Quantarctica is used not only by scientists but also by environmental managers, logistics operators, outreach specialists, and even educators in classrooms. We have Quantarctica users in most countries that are active in Antarctica. Global mirror sites in Hobart, Tokyo, Goa, and Minneapolis enable smoother downloads for the international community. LET’S TAKE A TOUR OF QUANTARCTICA!

Scientific data are categorised according to various scientific disciplines. Colours and colour ramps were

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IN BRIEF

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Locations of Antarctic research stations shown on the detailed basemap. Users can choose which data layers are shown by clicking boxes in the left column.

This screenshot shows ice movement. Slowly moving inland ice (purple, moves only a few metres per year) is channeled into fast-moving glaciers (blues and greens, move 100-500 metres per year) and flows beyond the grounding line (white curve), becoming a floating ice shelf. Arrows show the direction of flow. Arrow lengths and the background colour show the flow speed. The location of the close-up map is shown in the panAntarctic map at the bottom left.

carefully chosen to be colourblind-friendly. Because the power of GIS is to see multiple data sets together, we styled the colours of relevant data layers to coordinate well together. We covered both observed and modeled data sets, and, when possible, we included layers representing data error so that non-specialists can understand the quality of the data without prior knowledge. On the top of these layers, we have SCAR registered names, facility names listed by the Council of Managers of National Antarctic Programs (COMNAP), a range of latitude and longitude lines, UTM zones, and other miscellaneous layers. Finally, all layers contain metadata, including a brief abstract for non-specialists, information on how to cite the data, pixel resolution, and any adjustments we made (often just a simple re-projection of the data).

If you work with or in Antarctica, download Quant­ arctica today to make maps for proposals and papers and develop field or data acquisition plans. You are free to add your own data sets. After work, don’t forget to explore regions you haven’t visited before, to find new surprises and enjoy eye-opening experiences. Even if you don’t have a professional interest in Antarctica, try Quantarctica to see the power of combining an integrated mapping environment with free software. Maybe you will be inspired to develop a similar tool for your own study area.

FURTHER READING: Quantarctica website: http://quantarctica.npolar.no

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RETROSPECTIVE

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Per Savio collecting penguin eggs. The two prefabricated huts, assembled into a single longhouse, can

ABOUT THE EXPEDITION

be seen in the background. These buildings are still standing, one of the few Norwegian cultural heritage monuments in the Antarctic. Photo: Carsten Borchgrevink

British Antarctic Expedition 1898-1900. The first British voyage of discovery during the heroic golden age of Antarctic exploration. Carsten Borchgrevink led an expedition funded by the English publisher George Newnes. The Southern Cross was originally a Norwegian ship. Only three of the 29 participants were British. The rest – with the exception of one Swede – were Norwegian.

FRAM FORUM 2019

RETROSPECTIVE

Ann Kristin Balto // Norwegian Polar Institute

Two Sámi among penguins in the Antarctic A Sámi makes his way through a colony of penguins. To make sense of this strange juxtaposition we must go back more than a century, to 1899, when Per Savio and Ole Must spent the winter on the least explored continent on the planet: Antarctica.

T

heir adventurous journey into the unknown started in May of 1898. Two childhood friends, Per Savio and Ole Must, said farewell to family and friends in Sør-Varanger and boarded a waiting British ship. The Southern Cross sailed south, via London and Hobart, ultimately arriving at Cape Adare in the Antarctic on 17 February 1899. A violent storm blew in just days after their arrival and the ship hastily had to put out to open sea to avoid being crushed by huge waves. Savio and Must, who remained ashore with the dogs, survived the storm in a lavvu, a large teepee-like structure commonly used by the Sámi people, which they had set up as a temporary shelter. After the storm they managed to set up two prefabricated huts where ten men would overwinter on a barren rocky beach inhabited by Adélie penguins. Per Savio and Ole Must were hired by the leader of the expedition, Carsten Borchgrevink, to tend the dogs. Borchgrevink’s objective was to find the magnetic South Pole and attempt to reach the pole itself, if possible. The expedition collected scientific data and made the first magnetic observations on the Antarctic mainland.

On the return voyage, Southern Cross sailed south into the Ross Sea until they reached the edge of the ice and discovered the Bay of Whales. Borchgrevink wanted to climb up and explore the ice shelf. Savio and William Colbeck (the expedition’s magnetic observer) accompanied him on the trip across the barrier by dogsledge. Borchgrevink, Savio and Colbeck reached 78° 50′ on 17 February 1900, farther south than anyone had ever been before. This record would stand until Scott and Shackleton surpassed it in 1902. The Southern Cross returned to Norway in the autumn of 1900, but the expedition received little attention. Norwegians considered it an English expedition, and in England, all eyes were turned to Robert Falcon Scott and his planned expedition to Antarctica the following year. The Norwegian Polar Institute photo archive includes photographs from the expedition: www.bildearkiv.npolar.no

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FRAM CENTRE FLAGSHIPS

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Projects in the Fram Centre Flagships for 2018

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FRAM CENTRE FLAGSHIPS

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Sea ice in the Arctic Ocean, Technology and Governance Sea ice, ecosystems & models RESEARCH AREAS/PROJECT TITLES

PARTNERS (LEAD PARTNER FIRST)

PROJECT LEADER

E-MAIL PROJECT LEADER

ALSIM - Automised Large-scale Sea Ice Mapping

UiT, MET, NPI

Torbjørn Eltoft

torbjorn.eltoft@uit.no

ICEHOT - Processes governing variable Arctic sea ice – the Barents Sea hotspot

IMR, UNIS, MET, PINRO, IOPAS

Vidar Lien

vidar.lien@hi.no

Long-term variability and trends in the Atlantic Water inflow region (ATWAIN)

NPI, IMR, UNIS, UiT, IOPAS, etc.

Paul A Dodd

paul.dodd@npolar.no

Mesoscale modeling of ice, ocean and ecology of the Arctic Ocean

APN, IMR, NPI, SINTEF, MET

Tore Hattermann

tore.hattermann@akvaplan.niva.no

Holocene ocean and sea ice history at north-east Svalbard – from past to present warm extremes

NPI, UiT, UNIS, BAS, NCAOR

Katrine Husum

katrine.husum@npolar.no

Using Tracers, Atmospheric Indices and Model Output to explain changes in the Arctic Ocean Inflow and Outflow through Fram Strait

NPI, NRPA, APN, IMR, OASYS

Paul A Dodd

paul.dodd@npolar.no

ArctisMOD - follow-up

NPI, APN, NIVA

Pedro Duarte

pedro.duarte@npolar.no

Assessment of ecosystem vulnerability and functioning in ice-affected waters - ICEEVA

IMR, UiT, UNIS/APN

L L Jørgensen

lis.lindal.joergensen@hi.no

Barents Sea harp seals in a changing Arctic

IMR, UiT, APN, PINRO, SMR, SAMS

K T Nilssen

kjell.tormod.nilssen@hi.no

UiT, NPI, MET, WU, SCNN

Maaike Knol

maaike.knol@uit.no

Arctic-BBNJ

UiT, IMR, FNI

Vito de Lucia

vito.delucia@uit.no

Polar ICE - Implementation, Compliance and Enforcement of the Polar Code in Arctic waters

NORUT, UiT, APN, Nord Uni, Kingston

Anne Katrine Normann

anno@norceresearch.no

A-LEX review

APN, UiT, Marintek

L H Larsen

Lars@akvaplan.niva.no

Ice floe interaction with ships and waves - IFiSaw

SINTEF, UiT, Northshore

Karl Gunnar Aarsæther

Karl.Gunnar.Aarsather@sintef.no

Arctic Ocean Monitoring using automated unmanned marine vehicles - workshop

APN, UiT, NPI etc.

Lionel Camus

lionel.camus@akvaplan.niva.no

Drivers and development of new industries Information systems in the Arctic Ocean

Regimes for sustainable development

Technology

Dissemination RESEARCH AREAS/PROJECT TITLES

PARTNERS

PROJECT LEADER

E-MAIL PROJECT LEADER

X-2068

Ice-9, several Fram Centre partners, Polaria, etc.

Christine Cynn

christine@ice-9.no

RESEARCH AREAS/PROJECT TITLES

PARTNERS (LEAD PARTNER FIRST)

PROJECT LEADER

E-MAIL PROJECT LEADER

Coordination, events, outreach, information

NPI, UiT, SINTEF

Arild Sundfjord

arild.sundfjord@npolar.no

Flagship common activities

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Effects of climate change on sea and coastal ecology in the North RESEARCH AREAS/PROJECT TITLES

LEAD PARTNER

PROJECT LEADER

E-MAIL PROJECT LEADER

EFFECTS: Examining the role of Fish-Falls on ECosystem processes in highly exploiTed fjord Systems

APN

Paul Renaud

paul.renaud@akvaplan.niva.no

Marine snow. Pelagic-benthic coupling, and the impact of the harpacticoid copepod Microsetella norvegica, and other agents in a high-latitude fjord (MICROSNOW)

UiT

Camilla Svensen

camilla.svensen@uit.no

Population abundance estimation of harbor porpoise from multi-type survey data (MULTI-PORPOISE)

IMR

Arne Bjørge

arne.bjoerge@hi.no

The impact of oceanic inflow and glacial runoff on the carbon budget in Kongsfjorden using field and model data (KongCarbon) – Phase II

IMR

Melissa Chierici

melissa.chierici@hi.no

Drivers of fish extinction and colonization on oceanic banks (DRIVEBANKS): adding management and social dimensions

NINA

Kari Ellingsen

Kari.Ellingsen@nina.no

Impact of massive Winter Herring Abundances on the KaLdfjorden Environment (WHALE)

IMR

Angelika Renner

angelika.renner@hi.no

Arctic harmful algae biosensor

APN

Lionel Camus

lionel.camus@akvaplan.niva.no

The new generation of Calanus finmarchicus: estimating population recruitment from egg production rates and gonad stage analysis off northern Norway (GONAD)

APN

Claudia Halsband

claudia.halsband@akvaplan.niva. no

The role of harbour porpoise in Norwegian coastal marine communities

IMR

Ulf Lindstrøm

ulf.lindstroem@hi.no

weShare – Ecological and commercial implications of extreme winter arrivals of herring and whales into North-Norwegian fjord systems

IMR

Martin Biuw

martin.biuw@hi.no

Meroplankton biodiversity, seasonal dynamics and function in high latitude coastal ecosystems

UNIS

Janne Søreide

janne.soreide@unis.no

Mapping sea ice

NPI

Sebastian Gerland

gerland@npolar.no

Climate-driven regime shifts in arctic rocky-bottom communities: Causation and implications for ecosystem functioning

UiT

Raul Primicerio

raul.primicerio@uit.no

Seabird habitat use and migration strategies

NINA

Børge Moe

borge.moe@nina.no

Urban kittiwakes: building artificial nestsites in Tromsø

NINA

Tone Reiertsen

tone.reiertsen@nina.no

Exploring the effects of sea ice variability on the downward flux of biogenic particles in Svalbard fjords

UNIS

Janne Søreide

janne.soreide@unis.no

RESEARCH AREAS/PROJECT TITLES

PARTNERS

PROJECT LEADER

E-MAIL PROJECT LEADER

Outreach activities: combining classic approaches and innovative outreach program integrating research, outreach and education

APN

Perrine Geraudie

perrine.geraudie@akvaplan.niva.no

X-2068

Ice-9

Anneli Stiberg

anneli@ice-9.no

Dissemination

FRAM FORUM 2019

FRAM CENTRE FLAGSHIPS

Effects of climate change on terrestrial ecosystems, landscapes, society and indigenous peoples Vegetation Transitions and Herbivores Impacts RESEARCH AREAS/PROJECT TITLES

PARTNERS (LEAD PARTNER FIRST)

PROJECT LEADER

E-MAIL PROJECT LEADER

After the Pest

NINA, UiT

Jane Jepsen

jane.jepsen@nina.no

Moose in Finnmark

NIBIO, NINA, UiT

Erling Meisingset

erling.meisingset@nibio.no

ECOGEN

UiT, NIBIO

Dilli Prasad Rijal

kari.brathen@uit.no

UAV Vegetation Mapping

NORUT, NIBIO

Corine Davids

corine.davids@norut.no

Effects of Changing Seasonality and Extreme Events Remote sensing

NIBIO, NORUT, UiT

Marit Jørgensen

Marit.Jorgensen@nibio.no

Growth and Decay

UiT, NINA, NORUT

Elisabeth Cooper

elisabeth.cooper@uit.no

Reindeer Health

UiT, VET, NINA, NORUT

Morten Tryland

morten.tryland@uit.no

Adaptive Capacity in Local Communities and among Indigenous Peoples LUMANOR

NIKU, UiT, NMBU

Stine Barlindhaug

stine@fam-barlindhaug.no

Socio-ecological modelling

NINA, NIKU, NMBU

Bård-Jørgen Bårdsen

bard.jorgen.bardsen@nina.no

Adaptive Management of Ecosystem Services Esarctic

UiT, NINA

Vera Hausner

vera.hausner@uit.no

SUSTAIN

UiT, NPI, NINA

John-Andre Henden

john-andre.henden@uit.no

WETLANDS

NINA, UiT, NMBU

Jarle Bjerke

jarle.bjerke@nina.no

COAT

UiT, NINA, NPI, UNIS, MET

Rolf Anker Ims

rolf.ims@uit.no

Yamal Ecosystem

UiT, NPI, NINA

Dorothee Ehrich

dorothee.ehrich@uit.no

Frame-by-Frame

NINA, UiT

Jane Jepsen

jane.jepsen@nina.no

Svalbardreinen

NPI

Åshild Ønvik Pedersen

ashild.pedersen@npolar.no

X-2068

Ice-9, Polaria, Fram Centre

Cristine Cynn

info@ice-9.no

Climate Impact Observation Systems

Scientific communication

139

140

FRAM CENTRE FLAGSHIPS

FRAM FORUM 2019

MIKON – Environmental consequences of industrial development in the North Knowledge basis for ecosystem-based management RESEARCH AREAS/PROJECT TITLES

PARTNERS (LEAD PARTNER FIRST)

PROJECT LEADER

E-MAIL PROJECT LEADER

Ocean Health in Transition

NINA, UiT, NIVA, IMR, Nofima

Per Fauchald

per.fauchald@nina.no

Oil Spill Modelling in Ice Covered Ocean – and environmental consequences (OSMICO)

MET, APN

Lars R Hole

lrh@met.no

Managing Variable Environmental Values

NPI, IMR

Ellen Øseth

ellen.oseth@npolar.no

Does aquaculture act as a source of micro- and macro plastic in the Arctic? – A pilotstudy (Aqua-Plast)

NILU, APN, IMR

Dorte Herzke

dorte.herzke@nilu.no

How to avoid conflicts between wild and farmed salmonids? -Finding good locations for aquaculture

APN, UiT, IMR

Jenny L A Jensen

jen@akvaplan.niva.no

Soundscapes in a Changing Arctic – Noise and Biota (SCAN-B)

NPI, UNIS, UiT

Kit M Kovacs

kit.kovacs@npolar.no

and elevated temperature (Sens2change)

UiT, APN, SINTEF, UNIS

Jasmine Nahrgang

jasmine.m.nahrgang@uit.no

Pollutant Availability and Mobility in Environmental Risk Assessment management tools (PAMERA)

APN, UiT, UNIS

Kristine B Pedersen

kbo@akvaplan.niva.no

Seabird moulting and chick rearing area in relation to planned oil activity in the southeastern Barents Sea

NINA, NPI, IMR

Kjell Einar Erikstad

kjell.erikstad@nina.no

Development of MODel for prediction of Eutrofication and SedimenTation from fish cage farms

APN, NORUT, UiT, NIVA

Ole Anders Nøst

oan@akvaplan.niva.no

Consequences for organisms and ecosystems

Sensitivity of polar cod early life stages to a changing Arctic: A study of the impact of petroleum

Integrated studies of environmental consequences Indigenous-industry governance interactions in the Arctic. Environmental impacts and knowledge basis for management (IndGov)

UiT, NIKU

Camilla Brattland

camilla.brattland@uit.no

The impact of extractive industries and tourism on socio-ecological dynamics in the Arctic

UiT, NINA

Vera Helene Hausner

vera.hausner@uit.no

Productivity effects in reindeer from changes in human land use – improving snow and vegetation map layers to facilitate sustainable land use

NINA, NMBU, UiT

Audun Stien

audun.stien@nina.no

Ecosystem services and coastal governance

NIKU, Nofima

Alma Thuestad

alma.thuestad@niku.no

FRAM FORUM 2019

FRAM CENTRE FLAGSHIPS

141

Hazardous substances – effects on ecosystems and human health Multiple stressors- combined impact of contaminants and climate change - birds RESEARCH AREAS/PROJECT TITLES

PARTNERS (LEAD PARTNER FIRST)

PROJECT LEADER

E-MAIL PROJECT LEADER

Multi-stress relationships in seabird populations: interactions between natural stressors and environmental contaminants

NINA, APN, NPI, NILU, UiT

Jan Bustnes

jan.bustnes@nina.no

Impacts of environmental contaminants and natural stressors on northern raptors: RAPTOR

NINA, NILU

Jan Bustnes

jan.bustnes@nina.no

Habitat and dietary specific accumulation of methylmercury in Arctic charr

NIVA, APN, NINA, UiT

H F Braathen

HansFredrik.VeitebergBraaten@ niva.no

POPs in Arctic char from a remote Arctic lake: Long-term trends and responses to changing inputs, fish ecology and a warming climate (FishTrend)

APN, NIVA, NILU

J Bytingsvik

jby@akvaplan.niva.no

NPI, APN, NILU, UiB

H Routti

heli.routti@npolar.no

Bjørnøya- Arctic charr effect studies

Marine mammals- contaminant levels and effects Giants of the ocean – affected by anthropogenic pollutants?

Model development -emerging contaminants and bioaccumulation in seabirds Atmospheric inputs of organic contaminants of emerging concern to the Arctic and possible implications for ecosystem exposure

NILU, APN

I Krogseth

isk@nilu.no

Development, evaluation, and application of a bioaccumulation model for organic contaminants in Arctic seabirds

NILU, APN, NINA, NPI

I Krogseth

isk@nilu.no

The effects of contaminants on human health and Arctic communities Evaluating the significance of spatial variability and body mass index (BMI) for human concentrations of persistent organic pollutants (POPs) in northern areas

NILU, UiT

An Environmental Risk Quotient for Arctic Communities

NILU, NORUT, IMR, UiT S Mudge

T Nøst

therese.h.nost@uit.no

smm@nilu.no

Impact from industrial development and urbanization in the North Fate and effects of pollutants on Arctic ecosystems Microplastics from artificial sports pitches: composition, degradation and biological interactions (MARS)

APN/NILU, SINTEF, IMR

C Halsband

claudia.halsband@akvaplan.niva. no

POPs adsorbing to Marine plastic litter in the Arctic marine environment acting as a new vector of exposure

NILU, NPI, SINTEF, UiT

D Herzke

dhe@nilu.no

Urban development, shipping and tourism impacts on marine ecosystem in Tromsø. Investigation of cocktail effects using bivalves as sentinel species

APN, NILU, UiT

P Geraudie

pge@akvaplan.niva.no

M Karlsson

marianne.karlsson@niva.no

Risk governance - Communicating and applying research results An Arctic risk governance regime for multiple stressors: the case of interaction between climate change and hazardous chemicals’ (ARIGO)

NIVA, APN, CICERO

142

FRAM CENTRE FLAGSHIPS

FRAM FORUM 2019

Ocean Acidification Ocean acidification state and drivers in Arctic waters (OA-State/OA-Drivers) RESEARCH AREAS/PROJECT TITLES

PARTNERS (LEAD PARTNER FIRST)

PROJECT LEADER

Times-series of carbonate chemistry, indicator parameters (OA-State)

NPI, IMR, NIVA, NPI, IMR

A Fransson

Climate drivers: impact of OA and other climate stressors (OA-Drivers)

NPI, IMR, NIVA, IMR, UiT, AWI

A Fransson

E-MAIL PROJECT LEADER

Sensitivity of Marine Biota to the Acidification of northern waters and its effects on marine ecosystems The effect of OA on gametes and vulnerable life stages

APN, IMR, NPI, FSU, UNIS, IMEDEA, ES

Järnegren

The effect of natural temporal and spatial variations in multiple OA drivers (pCO2, salinity and temperature) on the physiology and skeletal properties of benthic and planktonic organisms

IMR, NPI, IOPAS, BangorU, JAMSTEC, NIVA

H Hop

Capacity for adaptation in Arctic invertebrates to multiple OA drivers (pCO2, salinity and temperature)

NPI, IMR, BOS, WHOI

H Browman, S Rastrick (IMR)

UndersTanding and PRedicting the acidification of northern waters and its iMpacts on marine ecosystems and biogeochemistry (TRUMP) Understanding regional OA using models

NIVA, IMR

P Wallhead

Projecting ecosystem response and feedbacks to OA

IMR, NIVA, IMR

Hansen

Local OA impacts from benthic drivers

NIVA, NPI

E Yakushev

Tracking and forecasting OA impacts on complex multi-species interactions

NPI, NIVA, IMR, Scripps, CSIRO

G Griffith

Risk governance and ocean acidification: understanding the role of uncertainty Expert elicitation to identify key uncertainties

SALT

J Falk-Andersson

Decision-makers understanding of uncertainties

NIVA

M Karlsson

Synthesis: risk governance and management options

NORUT, ASU

Norman

ABBREVIATIONS APN: Akvaplan-niva AS; ASU: Arizona State University; AWI: Alfred Wegener Institute; BAS: British Antarctic Survey; BOS: Bigelow Laboratory for Ocean Science; BangorU: Bangor University; CICERO: Center for International Climate Research; CSIRO: Commonwealth Scientific and Industrial Research Organisation; FNI: Fridtjof Nansen Institute; FSU: Florida State University; JAMSTEC: Japan Agency for Marine-Earth Science and Technology; Ice-9: Ice-9 is a media/outreach consultancy firm; IMEDEA: Mediterranean Institute for Advanced Studies; IMR: Institute of Marine Research; IOPAS: Institute of Oceanology, Polish Academy of Sciences; Kingston: Michael Kingston Associates; Marintek: Marine Technology Research Institute; MET: The Norwegian Meteorological Institute; NCAOR: National Centre for Antarctic and Ocean Research; NIBIO: The Norwegian Institute of Bioeconomy Research; NINA: Norwegian Institute for Nature Research; NIKU: The Norwegian Institute for Cultural Heritage Research; NILU: Norwegian Institute for Air Research; NIVA: Norwegian Institute for Water Research; NMBU: Norwegian University of Life Sciences; Nofima: The Norwegian Institute of Food, Fisheries and Aquaculture Research; Nord Uni: Nord University; Northshore: Northshore shipping company; NORUT: Northern Research Institute; NPI: Norwegian Polar Institute; NRPA: Norwegian Radiation Protection Authority; OASYS: Ocean Atmosphere Systems - Research; PINRO: Polar Research Institute of Marine Fisheries and Oceanography; SALT: Salt Lofoten AS; SAMS: The Scottish Association for Marine Science; SCNN: Science Centre of Northern Norway; SINTEF: The Company for Industrial and Technological Research; Scripps: Scripps Institution of Oceanography; SMR: Sea Mammal Research Unit; UiB: University of Bergen; UiT: UiT The Arctic University of Norway; UNIS: The University Centre in Svalbard; VET: Norwegian Veterinary Institute; WHOI: Woods Hole Oceanographic Institution; WU: Wageningen University

FRAM FORUM 2018

CONTACT INFORMATION

143

Contact information FRAM – the High North Research Centre for Climate and the Environment Fram Centre AS Ph: +47 7775 0200 Fram Institutions at the Fram Centre building Visiting address: Hjalmar Johansens gate 14 Postal address: POB 6606 Langnes N-9296 Tromsø Ph: +47 7775 0200 Web: www.framsenteret.no Akvaplan-niva AS Ph: +47 7775 0300 www.akvaplan.niva.no Geological Survey of Norway Ph: +47 7775 0125 www.ngu.no Institute of Marine Research Tromsø Ph: +47 5523 8500 www.imr.no Norwegian Coastal Administration Ph: 07 847, International calls +47 3303 4308 www.kystverket.no NILU – Norwegian Institute for Air Research Ph: +47 6389 8000 www.nilu.no Norwegian Institute for Cultural Heritage Research Ph: +47 7775 0400 niku.no Norwegian Institute for Nature Research Ph: +47 7775 0400 nina.no Norwegian Mapping Authority Tromsø Ph: 08 700, International calls +47 3211 8121 www.statkart.no Norwegian Polar Institute Ph: +47 7775 0500 www.npolar.no Norwegian Radiation Protection Authority Ph: +47 7775 0170 www.nrpa.no

FRAM institutions elsewhere

Other institutions at the Fram Centre

CICERO – Center for International Climate and Environmental Research Ph: +47 2285 8750 www.cicero.uio.no

Arctic Council Secretariat Ph: +47 7775 0140 arctic-council.org

NOFIMA Muninbakken 9-13 Breivika POB 6122, N-9291 Tromsø Ph: +47 7762 9000 www.nofima.no NIBIO – Norwegian Institute of Bioeconomy Research POB 2284 Tromsø postterminal, N-9269 Tromsø Ph: 03 246, International calls: +47 4060 4100 www.nibio.no NORCE POB 6434 Forskningsparken, N-9294 Tromsø Ph: +47 7762 9400 Fax: +47 7762 9401 www.norceresearch.no Norwegian Meteorological Institute Main office: Henrik Mohns plass 1, N-0310 Oslo Forecasting Division of Northern Norway: Kirkegårdsveien 60, N-9293 Tromsø Ph: +47 7762 1 00 met.no Norwegian School of Veterinary Science Dept. of Arctic Veterinary Medicine Stakkevollveien 23, N-9010 Tromsø Ph: +47 7766 5400 www.veths.no Norwegian Veterinary Institute Stakkevollveien 23, N-9010 Tromsø Ph: +47 7761 9230 www.vetinst.no SINTEF Nord AS POB 118, N-9252 Tromsø Ph: +47 7359 3000 www.sintef.no University Centre in Svalbard (UNIS) POB 156, N-9171 Longyearbyen Ph: +47 7902 3300 www.unis.no UiT The Arctic University of Norway N-9037 Tromsø Ph: +47 7764 4000 uit.no

AMAP Arctic Monitoring and Assessment Programme www.amap.no BarentsWatch Phone: 07847 International calls: +47 3303 4808 www.barentswatch.no Centre for the Ocean and the Arctic www.oceanarctic.org International Centre for Reindeer Husbandry www.reindeerherding.org Polaria Visitors’ Centre Hjalmar Johansens gate 12, N-9296 Tromsø Ph: +47 7775 0100 www.polaria.no

Fram Centre Framsenteret, POB 6606 Langnes N – 9296 Tromsø – Phone: +47 77 75 02 00 Fax: +47 77 75 02 01 E-mail: post@framsenteret.no www.framsenteret.no

Print version: ISSN 1893-5532 Online version: ISSN 8193-5540