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24 results on '"Aas, Kjetil Schanke"'

1. Impacts of irrigation expansion on moist-heat stress based on IRRMIP results.

Author

Yao, Yi, Ducharne, Agnès, Cook, Benjamin I., De Hertog, Steven J., Aas, Kjetil Schanke, Arboleda-Obando, Pedro F., Buzan, Jonathan, Colin, Jeanne, Costantini, Maya, Decharme, Bertrand, Lawrence, David M., Lawrence, Peter, Leung, L. Ruby, Lo, Min-Hui, Devaraju, Narayanappa, Wieder, William R., Wu, Ren-Jie, Zhou, Tian, Jägermeyr, Jonas, and McDermid, Sonali

Subjects
WATER withdrawals, IRRIGATION water, ATMOSPHERIC temperature, STRUCTURAL models, IRRIGATION
Abstract

Irrigation rapidly expanded during the 20th century, affecting climate via water, energy, and biogeochemical changes. Previous assessments of these effects predominantly relied on a single Earth System Model, and therefore suffered from structural model uncertainties. Here we quantify the impacts of historical irrigation expansion on climate by analysing simulation results from six Earth system models participating in the Irrigation Model Intercomparison Project (IRRMIP). Results show that irrigation expansion causes a rapid increase in irrigation water withdrawal, which leads to less frequent 2-meter air temperature heat extremes across heavily irrigated areas (≥4 times less likely). However, due to the irrigation-induced increase in air humidity, the cooling effect of irrigation expansion on moist-heat stress is less pronounced or even reversed, depending on the heat stress metric. In summary, this study indicates that irrigation deployment is not an efficient adaptation measure to escalating human heat stress under climate change, calling for carefully dealing with the increased exposure of local people to moist-heat stress. Although irrigation expansion during the 20th century masked or even reversed local warming trends over some intensely irrigated regions, the exposure to moist-heat extremes of local population has increased due to higher air humidity. [ABSTRACT FROM AUTHOR]

Published
2025
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4. Climate–ecosystem modelling made easy: The Land Sites Platform

Author

Keetz, Lasse Torben, Lieungh, Eva, Karimi-Asli, Kaveh, Geange, Sonya Rita, Gelati, Emiliano, Tang, Hui, Yilmaz, Yeliz A., Aas, Kjetil Schanke, Althuizen, Inge, Bryn, Anders, Falk, Stefanie, Fisher, Rosie, Fouilloux, Anne, Horvath, Peter, Indrehus, Sunniva, Lee, Hanna, Lombardozzi, Danica, Parmentier, Frans-Jan W., Pirk, Norbert, Vandvik, Vigdis, Vollsnes, Ane Victoria, Skarpaas, Olav, Stordal, Frode, and Tallaksen, Lena M.

Abstract

Dynamic Global Vegetation Models (DGVMs) provide a state-of-the-art process-based approach to study the complex interplay between vegetation and its physical environment. For example, they help to predict how terrestrial plants interact with climate, soils, disturbance and competition for resources. We argue that there is untapped potential for the use of DGVMs in ecological and ecophysiological research. One fundamental barrier to realize this potential is that many researchers with relevant expertize (ecology, plant physiology, soil science, etc.) lack access to the technical resources or awareness of the research potential of DGVMs. Here we present the Land Sites Platform (LSP): new software that facilitates single-site simulations with the Functionally Assembled Terrestrial Ecosystem Simulator, an advanced DGVM coupled with the Community Land Model. The LSP includes a Graphical User Interface and an Application Programming Interface, which improve the user experience and lower the technical thresholds for installing these model architectures and setting up model experiments. The software is distributed via version-controlled containers; researchers and students can run simulations directly on their personal computers or servers, with relatively low hardware requirements, and on different operating systems. Version 1.0 of the LSP supports site-level simulations. We provide input data for 20 established geo-ecological observation sites in Norway and workflows to add generic sites from public global datasets. The LSP makes standard model experiments with default data easily achievable (e.g., for educational or introductory purposes) while retaining flexibility for more advanced scientific uses. We further provide tools to visualize the model input and output, including simple examples to relate predictions to local observations. The LSP improves access to land surface and DGVM modelling as a building block of community cyberinfrastructure that may inspire new avenues for mechanistic ecosystem research across disciplines. publishedVersion

Published
2023

5. Explicitly modelling microtopography in permafrost landscapes in a land surface model (JULES vn5.4_microtopography)

Author

Smith, Noah D., Burke, Eleanor J., Aas, Kjetil Schanke, Althuizen, Inge H. J., Boike, Julia, Christiansen, Casper Tai, Etzelmüller, Bernd, Friborg, Thomas, Lee, Hanna, Rumbold, Heather, Turton, Rachael H., Westermann, Sebastian, Chadburn, Sarah E., Smith, Noah D., Burke, Eleanor J., Aas, Kjetil Schanke, Althuizen, Inge H. J., Boike, Julia, Christiansen, Casper Tai, Etzelmüller, Bernd, Friborg, Thomas, Lee, Hanna, Rumbold, Heather, Turton, Rachael H., Westermann, Sebastian, and Chadburn, Sarah E.

Abstract

Microtopography can be a key driver of heterogeneity in the ground thermal and hydrological regime of permafrost landscapes. In turn, this heterogeneity can influence plant communities, methane fluxes, and the initiation of abrupt thaw processes. Here we have implemented a two-tile representation of microtopography in JULES (the Joint UK Land Environment Simulator), where tiles are representative of repeating patterns of elevation difference. Tiles are coupled by lateral flows of water, heat, and redistribution of snow, and a surface water store is added to represent ponding. Simulations are performed of two Siberian polygon sites, (Samoylov and Kytalyk) and two Scandinavian palsa sites (Stordalen and Iškoras). The model represents the observed differences between greater snow depth in hollows vs. raised areas well. The model also improves soil moisture for hollows vs. the non-tiled configuration ("standard JULES") though the raised tile remains drier than observed. The modelled differences in snow depths and soil moisture between tiles result in the lower tile soil temperatures being warmer for palsa sites, as in reality. However, when comparing the soil temperatures for July at 20ĝ€¯cm depth, the difference in temperature between tiles, or "temperature splitting", is smaller than observed (3.2 vs. 5.5ĝ€¯ĝ C). Polygons display small (0.2ĝ€¯ĝ C) to zero temperature splitting, in agreement with observations. Consequently, methane fluxes are near identical (+0ĝ€¯% to 9ĝ€¯%) to those for standard JULES for polygons, although they can be greater than standard JULES for palsa sites (+10ĝ€¯% to 49ĝ€¯%). Through a sensitivity analysis we quantify the relative importance of model processes with respect to soil moisture and temperatures, identifying which parameters result in the greatest uncertainty in modelled temperature. Varying the palsa elevation between 0.5 and 3ĝ€¯m has little effect on modelled soil temperatures, showing that using only two tiles can still be a v

Published
2022

6. LATICE MIP evapotranspiration – A model intercomparison project for evapotranspiration estimates at high latitudes

Author

Engeland, Kolbjorn, primary, Aas, Kjetil Schanke, additional, Erlandsen, Helene Birkelund, additional, Gelati, Emiliano, additional, Huang, Shaochun, additional, Narayanappa, Devaraju, additional, Pirk, Norbert, additional, Silantyeva, Olga, additional, Tallaksen, Lena Merete, additional, Vatne, Astrid, additional, and Yilmaz, Yeliz, additional

Published
2022
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9. Explicitly modelling microtopography in permafrost landscapes in a land-surface model (JULES vn5.4_microtopography)

Author

Smith, Noah D., Chadburn, Sarah E., Burke, Eleanor J., Aas, Kjetil Schanke, Althuizen, Inge H. J., Boike, Julia, Christiansen, Casper Tai, Etzelmüller, Bernd, Friborg, Thomas, Lee, Hanna, Rumbold, Heather, Turton, Rachael, Westermann, Sebastian, Smith, Noah D., Chadburn, Sarah E., Burke, Eleanor J., Aas, Kjetil Schanke, Althuizen, Inge H. J., Boike, Julia, Christiansen, Casper Tai, Etzelmüller, Bernd, Friborg, Thomas, Lee, Hanna, Rumbold, Heather, Turton, Rachael, and Westermann, Sebastian

Abstract

Microtopography can be a key driver of heterogeneity in the ground thermal and hydrological regime of permafrost landscapes. In turn, this heterogeneity can influence plant communities, methane fluxes and the initiation of abrupt thaw processes. Here we have implemented a two-tile representation of microtopography in JULES (the Joint UK Land Environment Simulator), where tiles are representative of repeating patterns of elevation difference. We evaluate the model against available spatially resolved observations at four sites, gauge the importance of explicitly representing microtopography for modelling methane emissions and quantify the relative importance of model processes and the model’s sensitivity its parameters. Tiles are coupled by lateral flows of water, heat and redistribution of snow. A surface water store is added to represent ponding. The model is parametrised using characteristic dimensions of landscape features at sites. Simulations are performed of two Siberian polygon sites, Samoylov and Kytalyk, and two Scandinavian palsa sites, Stordalen and Iškoras. The model represents the observed differences between greater snow depth in hollows vs raised areas well. The model also improves soil moisture for hollows vs the non-tiled configuration (‘standard JULES’) though the raised tile remains drier than observed. For the two palsa sites, it is found that drainage needs to be impeded from the lower tile, representing the non-permafrost mire, to achieve the observed soil saturation. This demonstrates the need for the landscape-scale drainage to be correctly modelled. Causes of moisture heterogeneity between tiles are decreased runoff from the low tile, differences in snowmelt, and high to low-tile water flow. Unsaturated flows between tiles are negligible, suggesting the adequacy of simpler water-table based models of lateral flow in wetland environments. The modelled differences in snow depths and soil moistures betwee

Published
2021

11. Overview of the Norwegian Earth System Model (NorESM2) and key climate response of CMIP6 DECK, historical, and scenario simulations

Author

Seland, Øyvind, primary, Bentsen, Mats, additional, Olivié, Dirk, additional, Toniazzo, Thomas, additional, Gjermundsen, Ada, additional, Graff, Lise Seland, additional, Debernard, Jens Boldingh, additional, Gupta, Alok Kumar, additional, He, Yan-Chun, additional, Kirkevåg, Alf, additional, Schwinger, Jörg, additional, Tjiputra, Jerry, additional, Aas, Kjetil Schanke, additional, Bethke, Ingo, additional, Fan, Yuanchao, additional, Griesfeller, Jan, additional, Grini, Alf, additional, Guo, Chuncheng, additional, Ilicak, Mehmet, additional, Karset, Inger Helene Hafsahl, additional, Landgren, Oskar, additional, Liakka, Johan, additional, Moseid, Kine Onsum, additional, Nummelin, Aleksi, additional, Spensberger, Clemens, additional, Tang, Hui, additional, Zhang, Zhongshi, additional, Heinze, Christoph, additional, Iversen, Trond, additional, and Schulz, Michael, additional

Published
2020
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14. Overview of the Norwegian Earth System Model (NorESM2) and key climate response of CMIP6 DECK, historical, and scenario simulations

Author

Seland, Øyvind, Bentsen, Mats, Olivié, Dirk, Toniazzo, Thomas, Gjermundsen, Ada, Seland Graff, Lise, Boldingh Debernard, Jens, Kumar Gupta, Alok, He, Yan-Chun, Kirkevåg, Alf, Schwinger, Jörg, Tjiputra, Jerry, Aas, Kjetil Schanke, Bethke, Ingo, Fan, Yuanchao, Griesfeller, Jan, Grini, Alf, Guo, Chuncheng, Ilicak, Mehmet, Hafsahl Karset, Inger Helene, Landgren, Oskar, Liakka, Johan, Onsum Moseid, Kine, Nummelin, Aleksi, Spensberger, Clemens, Tang, Hui, Zhang, Zhongshi, Heinze, Christoph, Iversen, Trond, Schulz, Michael, Seland, Øyvind, Bentsen, Mats, Olivié, Dirk, Toniazzo, Thomas, Gjermundsen, Ada, Seland Graff, Lise, Boldingh Debernard, Jens, Kumar Gupta, Alok, He, Yan-Chun, Kirkevåg, Alf, Schwinger, Jörg, Tjiputra, Jerry, Aas, Kjetil Schanke, Bethke, Ingo, Fan, Yuanchao, Griesfeller, Jan, Grini, Alf, Guo, Chuncheng, Ilicak, Mehmet, Hafsahl Karset, Inger Helene, Landgren, Oskar, Liakka, Johan, Onsum Moseid, Kine, Nummelin, Aleksi, Spensberger, Clemens, Tang, Hui, Zhang, Zhongshi, Heinze, Christoph, Iversen, Trond, and Schulz, Michael

Abstract

The second version of the coupled Norwegian Earth System Model (NorESM2) is presented and evaluated. NorESM2 is based on the second version of the Community Earth System Model (CESM2) and shares with CESM2 the computer code infrastructure and many Earth system model components. However, NorESM2 employs entirely different ocean and ocean biogeochemistry models. The atmosphere component of NorESM2 (CAM-Nor) includes a different module for aerosol physics and chemistry, including interactions with cloud and radiation; additionally, CAM-Nor includes improvements in the formulation of local dry and moist energy conservation, in local and global angular momentum conservation, and in the computations for deep convection and air-sea fluxes. The surface components of NorESM2 have minor changes in the albedo calculations and to land and sea-ice models. We present results from simulations with NorESM2 that were carried out for the sixth phase of the Coupled Model Intercomparison Project (CMIP6). Two versions of the model are used: one with lower (similar to 2 degrees) atmosphere-land resolution and one with medium (similar to 1 degrees) atmosphere-land resolution. The stability of the pre-industrial climate and the sen- sitivity of the model to abrupt and gradual quadrupling of CO2 are assessed, along with the ability of the model to simulate the historical climate under the CMIP6 forcings. Compared to observations and reanalyses, NorESM2 represents an improvement over previous versions of NorESM in most aspects. NorESM2 appears less sensitive to greenhouse gas forcing than its predecessors, with an estimated equilibrium climate sensitivity of 2.5 K in both resolutions on a 150-year time frame; however, this estimate increases with the time window and the climate sensitivity at equilibration is much higher. We also consider the model response to future scenarios as defined by selected Shared Socioeconomic Pathways (SSPs) from the Scenario Model Intercomparison Project defined

Published
2020
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17. Pathways of ice-wedge degradation in polygonal tundra under different hydrological conditions

Author

Nitzbon, Jan, Langer, Moritz, Westermann, Sebastian, Martin, Léo, Aas, Kjetil Schanke, Boike, Julia, Nitzbon, Jan, Langer, Moritz, Westermann, Sebastian, Martin, Léo, Aas, Kjetil Schanke, and Boike, Julia

Abstract

Ice-wedge polygons are common features of lowland tundra in the continuous permafrost zone and prone to rapid degradation through melting of ground ice. There are many interrelated processes involved in ice-wedge thermokarst and it is a major challenge to quantify their influence on the stability of the permafrost underlying the landscape. In this study we used a numerical modelling approach to investigate the degradation of ice wedges with a focus on the influence of hydrological conditions. Our study area was Samoylov Island in the Lena River delta of northern Siberia, for which we had in situ measurements to evaluate the model. The tailored version of the CryoGrid 3 land surface model was capable of simulating the changing microtopography of polygonal tundra and also regarded lateral fluxes of heat, water, and snow. We demonstrated that the approach is capable of simulating ice-wedge degradation and the associated transition from a low-centred to a high-centred polygonal microtopography. The model simulations showed ice-wedge degradation under recent climatic conditions of the study area, irrespective of hydrological conditions. However, we found that wetter conditions lead to an earlier onset of degradation and cause more rapid ground subsidence. We set our findings in correspondence to observed types of ice-wedge polygons in the study area and hypothesized on remaining discrepancies between modelled and observed ice-wedge thermokarst activity. Our quantitative approach provides a valuable complement to previous, more qualitative and conceptual, descriptions of the possible pathways of ice-wedge polygon evolution. We concluded that our study is a blueprint for investigating thermokarst landforms and marks a step forward in understanding the complex interrelationships between various processes shaping ice-rich permafrost landscapes.

Published
2019

21. Ozone suppression of carbon uptake by vegetation : A model study of the effect of ozone on carbon uptake and storage in boreal forests in northern Europe

Author

Aas, Kjetil Schanke

Abstract

Det er kjent at ozon har skadelig effekt på både mennesker og vegetasjon, i tillegg til å ha en negativ effekt på klimaet gjennom et direkte strålingspådriv. I tillegg har nyere studier vist at ozon også har en inndirekte effekt på klimaet ved å hemme opptak av karbon til vegetasjon. Formålet med dette studiet er å kaste lys over hva dagens, tidligere og fremtidige ozonkosentrasjoner betyr for strålingsbalansen til atmosfæren ved å redusere opptak av CO2 til vegetasjon, med spesielt fokus på boreal skog i nordeuropa. Med dette målet for øyet brukes en regional klimamodell koblet med kjemi (WRF-chem) til å simulere ozonkonsentrasjoner i nordeuropa for året 2009. Disse konsentrasjonene sammenlignes med observasjoner fre EMEP-nettverket, og brukes deretter i en landmodell (NoahMP) uten tilbakekoblinger, som er endret til å inkludere ozoneffekter på planter. NoahMP modellen er validert med målinger fra SMEAR II stasjonen, og brukes til å simulere endringer i total lagret karbon i boreal skog i nordeuropa. I tillegg brukes resultater fra OsloCTM-simuleringer til å produsere konsentrasjoner som er representative for år 1900 og år 2100 under SRES A2 senarioet. Endringene i totalt karbon sammenlignet med simuleringene uten ozoneffekter viser en klar innvirkning av ozon ved dagens konsentrasjoner som resulterer i betydelig reduksjon i totalt lagret karbon. Økningen i landkarbon fra 1900 til 2009 på grunn av økt atmosfærisk CO2 blir betydelig redusert på grunn av økning i ozonkonsentrasjoner, mens 2100 simuleringene viser en redusert effekt av ozon, selv for områder med betydelig økning i ozonkonsentrasjoner som følge av redusert stomata konduktans på grunn av økende CO2 konsentrasjoner.

Published
2012

22. Overview of the Norwegian Earth System Model (NorESM2) and key climate response of CMIP6 DECK, historical, and scenario simulations

Author

Seland, Øyvind, Bentsen, Mats, Oliviè, Dirk Jan Leo, Toniazzo, Thomas, Gjermundsen, Ada, Graff, Lise Seland, Debernard, Jens Boldingh, Gupta, Alok Kumar, He, Yan-Chun, Kirkevåg, Alf, Schwinger, Jörg, Tjiputra, Jerry, Aas, Kjetil Schanke, Bethke, Ingo, Fan, Yuanchao, Griesfeller, Jan, Grini, Alf, Guo, Chuncheng, Ilicak, Mehmet, Karset, Inger Helene H, Landgren, Oskar Andreas, Liakka, Johan, Moseid, Kine Onsum, Nummelin, Aleksi, Spensberger, Clemens, Tang, Hui, Zhang, Zhongshi, Heinze, Christoph, Iversen, Trond, and Schulz, Michael

Subjects
13. Climate action, 14. Life underwater, 7. Clean energy
Abstract

The second version of the coupled Norwegian Earth System Model (NorESM2) is presented and evaluated. NorESM2 is based on the second version of the Community Earth System Model (CESM2) and shares with CESM2 the computer code infrastructure and many Earth system model components. However, NorESM2 employs entirely different ocean and ocean biogeochemistry models. The atmosphere component of NorESM2 (CAM-Nor) includes a different module for aerosol physics and chemistry, including interactions with cloud and radiation; additionally, CAM-Nor includes improvements in the formulation of local dry and moist energy conservation, in local and global angular momentum conservation, and in the computations for deep convection and air–sea fluxes. The surface components of NorESM2 have minor changes in the albedo calculations and to land and sea-ice models. We present results from simulations with NorESM2 that were carried out for the sixth phase of the Coupled Model Intercomparison Project (CMIP6). Two versions of the model are used: one with lower (∼ 2∘) atmosphere–land resolution and one with medium (∼ 1∘) atmosphere–land resolution. The stability of the pre-industrial climate and the sensitivity of the model to abrupt and gradual quadrupling of CO2are assessed, along with the ability of the model to simulate the historical climate under the CMIP6 forcings. Compared to observations and reanalyses, NorESM2 represents an improvement over previous versions of NorESM in most aspects. NorESM2 appears less sensitive to greenhouse gas forcing than its predecessors, with an estimated equilibrium climate sensitivity of 2.5 K in both resolutions on a 150-year time frame; however, this estimate increases with the time window and the climate sensitivity at equilibration is much higher. We also consider the model response to future scenarios as defined by selected Shared Socioeconomic Pathways (SSPs) from the Scenario Model Intercomparison Project defined under CMIP6. Under the four scenarios (SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5), the warming in the period 2090–2099 compared to 1850–1879 reaches 1.3, 2.2, 3.0, and 3.9 K in NorESM2-LM, and 1.3, 2.1, 3.1, and 3.9 K in NorESM-MM, robustly similar in both resolutions. NorESM2-LM shows a rather satisfactory evolution of recent sea-ice area. In NorESM2-LM, an ice-free Arctic Ocean is only avoided in the SSP1-2.6 scenario.

23. Overview of the Norwegian Earth System Model (NorESM2) and key climate response of CMIP6 DECK, historical, and scenario simulations

Author

Seland, Øyvind, Bentsen, Mats, Oliviè, Dirk Jan Leo, Toniazzo, Thomas, Gjermundsen, Ada, Graff, Lise Seland, Debernard, Jens Boldingh, Gupta, Alok Kumar, He, Yan-Chun, Kirkevåg, Alf, Schwinger, Jörg, Tjiputra, Jerry, Aas, Kjetil Schanke, Bethke, Ingo, Fan, Yuanchao, Griesfeller, Jan, Grini, Alf, Guo, Chuncheng, Ilicak, Mehmet, Karset, Inger Helene H, Landgren, Oskar Andreas, Liakka, Johan, Moseid, Kine Onsum, Nummelin, Aleksi, Spensberger, Clemens, Tang, Hui, Zhang, Zhongshi, Heinze, Christoph, Iversen, Trond, and Schulz, Michael

Subjects
13. Climate action, 14. Life underwater, 7. Clean energy
Abstract

The second version of the coupled Norwegian Earth System Model (NorESM2) is presented and evaluated. NorESM2 is based on the second version of the Community Earth System Model (CESM2) and shares with CESM2 the computer code infrastructure and many Earth system model components. However, NorESM2 employs entirely different ocean and ocean biogeochemistry models. The atmosphere component of NorESM2 (CAM-Nor) includes a different module for aerosol physics and chemistry, including interactions with cloud and radiation; additionally, CAM-Nor includes improvements in the formulation of local dry and moist energy conservation, in local and global angular momentum conservation, and in the computations for deep convection and air–sea fluxes. The surface components of NorESM2 have minor changes in the albedo calculations and to land and sea-ice models. We present results from simulations with NorESM2 that were carried out for the sixth phase of the Coupled Model Intercomparison Project (CMIP6). Two versions of the model are used: one with lower (∼ 2∘) atmosphere–land resolution and one with medium (∼ 1∘) atmosphere–land resolution. The stability of the pre-industrial climate and the sensitivity of the model to abrupt and gradual quadrupling of CO2 are assessed, along with the ability of the model to simulate the historical climate under the CMIP6 forcings. Compared to observations and reanalyses, NorESM2 represents an improvement over previous versions of NorESM in most aspects. NorESM2 appears less sensitive to greenhouse gas forcing than its predecessors, with an estimated equilibrium climate sensitivity of 2.5 K in both resolutions on a 150-year time frame; however, this estimate increases with the time window and the climate sensitivity at equilibration is much higher. We also consider the model response to future scenarios as defined by selected Shared Socioeconomic Pathways (SSPs) from the Scenario Model Intercomparison Project defined under CMIP6. Under the four scenarios (SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5), the warming in the period 2090–2099 compared to 1850–1879 reaches 1.3, 2.2, 3.0, and 3.9 K in NorESM2-LM, and 1.3, 2.1, 3.1, and 3.9 K in NorESM-MM, robustly similar in both resolutions. NorESM2-LM shows a rather satisfactory evolution of recent sea-ice area. In NorESM2-LM, an ice-free Arctic Ocean is only avoided in the SSP1-2.6 scenario.

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