ice2ice

Below you can find a list of ice2ice peer reviewed publications. We have also produced a number of videos, which you can find on here.

2019

• Scussolini, Paolo, et al. “Agreement between reconstructed and modeled boreal precipitation of the Last Interglacial.” Science Advances 5.11 (2019): eaax7047.
• Rugenstein, Maria, et al. “Equilibrium climate sensitivity estimated by equilibrating climate models.” Geophysical Research Letters (2019).
• Grinsted, Aslak, Peter Ditlevsen, and Jens Hesselbjerg Christensen. “Normalized US hurricane damage estimates using area of total destruction, 1900− 2018.” Proceedings of the National Academy of Sciences (2019).
• de Vernal, Anne, et al. “Distribution of common modern dinoflagellate cyst taxa in surface sediments of the Northern Hemisphere in relation to environmental parameters: The new n= 1968 database.” Marine Micropaleontology (2019): 101796.
• Schmidt, Niels Martin, et al. “An ecosystem-wide reproductive failure with more snow in the Arctic.” PLoS biology 17.10 (2019): e3000392.
• Griem, Lisa, et al. “Insolation and glacial meltwater influence on sea‐ice and circulation variability in the northeastern Labrador Sea during the last Glacial.” Paleoceanography and Paleoclimatology (2019).
• Simonsen et al., “East Greenland ice core dust record reveals timing of Greenland ice sheet advance and retreat”, Nature communications, 10, 4494, (2019)
• Sessford, E. G., et al. “Consistent fluctuations in intermediate water temperature off the coast of Greenland and Norway during Dansgaard-Oeschger events.” Quaternary Science Reviews 223 (2019): 105887.
• MacFerrin, M. et al. “Rapid expansion of Greenland’s low-permeability ice slabs” Nature, volume 573, 403–407 (2019)
• Sadatzki, Henrik, et al. “Paired Li/Ca and δ18O peaks in bivalve shells from the Gulf of Panama mark seasonal coastal upwelling.” Chemical Geology (2019): 119295.
• King, A. C. F., et al. “Organic compounds in a sub‐Antarctic ice core: A potential suite of sea ice markers.” Geophysical Research Letters (2019).
• Pedersen, R. A., & Christensen, J. H. ( 2019). Attributing Greenland warming patterns to regional Arctic sea ice loss. Geophysical Research Letters, 46. https://doi.org/10.1029/2019GL083828
• Plach, Andreas, et al. “Eemian Greenland ice sheet simulated with a higher-order model shows strong sensitivity to SMB forcing.” (2019).
• De Schepper, Stijn, et al. “The potential of sedimentary ancient DNA for reconstructing past sea ice evolution.” The ISME Journal (2019): 1.
• Schrot, Oliver Gerald, Jens Hesselbjerg Christensen, and Herbert Formayer. “Greenland winter tourism in a changing climate.” Journal of Outdoor Recreation and Tourism 27 (2019): 100224.
• Mottram, Ruth, et al. “An Integrated View of Greenland Ice Sheet Mass Changes Based on Models and Satellite Observations.” (2018).
• Langehaug, Helene R., et al. “Variability along the Atlantic water pathway in the forced Norwegian Earth System Model.” Climate dynamics 52.1-2 (2019): 1211-1230.
• Christensen, Jens Hesselbjerg, et al. “Robustness of European climate projections from dynamical downscaling.” Climate Dynamics (2019): 1-13.
• Holme, Christian, et al. “Varying regional δ 18 O–temperature relationship in high-resolution stable water isotopes from east Greenland.” Climate of the Past 15.3 (2019): 893-912.
• Nielsen, Søren B., et al. “Two‐timescale carbon cycle response to an AMOC collapse.” Paleoceanography and Paleoclimatology (2019).
• Winstrup, Mai, et al. “A 2700-year annual timescale and accumulation history for an ice core from Roosevelt Island, West Antarctica.” Climate of the Past 15 (2019): 751-779.
• Muschitiello, Francesco, et al. “Deep-water circulation changes lead North Atlantic climate during deglaciation.” Nature Communications 10.1 (2019): 1272.
• Sadatzki, Henrik, et al. “Sea ice variability in the southern Norwegian Sea during glacial Dansgaard-Oeschger climate cycles.” Science Advances 5.3 (2019): eaau6174.
• Zamani, Behnam, et al. “Fram Strait sea ice export affected by thinning: comparing high-resolution simulations and observations.” Climate Dynamics (2019): 1-14.
• Lisé-Pronovost, Agathe, et al. “Scientific drilling of sediments at Darwin Crater, Tasmania.” (2019).
• Guo, Chuncheng, et al. “Description and evaluation of NorESM1-F: a fast version of the Norwegian Earth System Model (NorESM).” Geoscientific Model Development 12.1 (2019): 343-362.

2018

• Matte, Dominic, et al. “Robustness and scalability of regional climate projections over Europe.” Frontiers in Environmental Science 6 (2018): 163.
• Mottram, Ruth, et al. “An Integrated View of Greenland Ice Sheet Mass Changes Based on Models and Satellite Observations.” (2018).
• Buizert et al., “Abrupt ice-age shifts in southern westerly winds and Antarctic climate forced from the north” Nature 563 (2018): 681-685
• Olesen, Martin, et al. “Robustness of high-resolution regional climate projections for Greenland: a method for uncertainty distillation.” Climate Research 76.3 (2018): 253-268.
• Geng, Marilena Sophie, Jens Hesselbjerg Hesselbjerg Christensen, and Torben Christensen. “Potential future methane emission hot spots in Greenland.” Environmental Research Letters (2018).
• Li, Camille, and Andreas Born. “Coupled atmosphere-ice-ocean dynamics in Dansgaard-Oeschger events.” Quaternary Science Reviews 203 (2019): 1-20.
• Risebrobakken, Bjørg, and Sarah Miche Patricia Berben. “Early Holocene establishment of the Barents Sea Arctic front.” Frontiers in Earth Science 6 (2018): 166.
• De Fleurian, Basile, et al. “SHMIP The subglacial hydrology model intercomparison Project.” Journal of Glaciology(2018): 1-20.
• Sessford, E. G., et al. “High resolution benthic Mg/Ca temperature record of the intermediate water in the Denmark Strait across D‐O stadial‐interstadial cycles.” Paleoceanography and Paleoclimatology (2018).
• Plach, Andreas, et al. “Eemian Greenland SMB strongly sensitive to model choice.” Climate of the Past 14.10 (2018): 1463-1485.
• Kahle, Emma C., et al. “A Generalized Approach to Estimating Diffusion Length of Stable Water Isotopes from Ice‐Core Data.” Journal of Geophysical Research: Earth Surface.
• Malmierca-Vallet, Irene, et al. “Simulating the Last Interglacial Greenland stable water isotope peak: The role of Arctic sea ice changes.” Quaternary Science Reviews 198 (2018): 1-14.
• Åkesson, H. et al. “Atmosphere-driven ice sheet mass loss paced by topography: Insights from modelling the south-western Scandinavian Ice Sheet.” Quaternary Science Reviews 195, 32-47.
• Steiger, N., Niscancioglu, K., et al. “Simulated retreat of Jakobshavn Isbræ since the Little Ice Age controlled by geometry. The Cryosphere 12, 2249-2266.
• Lee J.E. et al. “An 83,000 year old ice core from Roosevelt Island, Ross Sea, Antarctica.” Climate of the Past, in review.
• Perner & Knudsen. “Two New Species of Recent and Upper Holocene Coccolith-agglutinated Foraminifera from the North Icelandic Shelf, North Atlantic.” J. of Foraminiferal Reserach 48 (3), 246-250.
• Pedro, Joel B., et al. “Beyond the bipolar seesaw: Toward a process understanding of interhemispheric coupling.” Quaternary Science Reviews 192 (2018): 27-46.
• Simonsen, Marius Folden, et al. “Particle shape accounts for instrumental discrepancy in ice core dust size distributions.” Climate of the Past 14.5 (2018): 601.
• Holme, Christian, Vasileios Gkinis, and Bo M. Vinther. “Molecular diffusion of stable water isotopes in polar firn as a proxy for past temperatures.” Geochimica et Cosmochimica Acta 225 (2018): 128-145.
• Boberg, F., et al. “21st-century climate change around Kangerlussuaq, west Greenland: From the ice sheet to the shores of Davis Strait.” Arctic, Antarctic, and Alpine Research50.1 (2018): S100006.
• Ogawa, Fumiaki, et al. “Evaluating impacts of recent Arctic sea‐ice loss on the northern hemisphere winter climate change.” Geophysical Research Letters (2018).
• Akperov, Mirseid, et al. “Cyclone activity in the Arctic from an ensemble of regional climate models (Arctic CORDEX).” Journal of Geophysical Research: Atmospheres 123.5 (2018): 2537-2554.
• Goelzer, H., et al. “Design and results of the ice sheet model initialisation experiments initMIP-Greenland: an ISMIP6 intercomparison.” The Cryosphere, 12, 1433-1460 (2018).
• Cuevas, Carlos A., et al. “Rapid increase in atmospheric iodine levels in the North Atlantic since the mid-20th century.” Nature Communications 9.1 (2018): 1452.
• Langehaug, H. R., et al. “Variability along the Atlantic water pathway in the forced Norwegian Earth System Model.” Climate Dynamics (2018): 1-20.
• Pyne, Rebecca L., et al. “A novel approach to process brittle ice for continuous flow analysis of stable water isotopes.” Journal of Glaciology (2018): 1-11.
• Jensen, Mari F., Kerim H. Nisancioglu, and Michael A. Spall. “Large changes in sea ice triggered by small changes in Atlantic water temperature.” Journal of Climate 2018 (2018).
• Luo, Yiming, et al. “Atlantic deep water circulation during the last interglacial.” Scientific reports 8.1 (2018): 4401.
• Schmith, Torben, et al. “Limited predictability of extreme decadal changes in the Arctic Ocean freshwater content.” Climate Dynamics (2018): 1-16.
• Cook, Eliza, et al. “First identification and characterization of Borrobol‐type tephra in the Greenland ice cores: new deposits and improved age estimates.” Journal of Quaternary Science33.2 (2018): 212-224.
• Poulsen et al. Parameterized and resolved Southern Ocean eddy compensation. Ocean Modelling, 2018
• Perner, Kerstin, et al. “Subarctic Front migration at the Reykjanes Ridge during the mid‐to late Holocene: evidence from planktic foraminifera.” Boreas 47.1 (2018): 175-188.

2017

• Cook et al. First identification of cryptotephra from the Kamchatka Peninsula in a Greenland ice core: Implications of a widespread marker deposit that links Greenland to the Pacific northwest. Quaternary Science Reviews, 2018
• Ahlstrøm et al, Abrupt shift in the observed runoff from the southwestern Greenland ice sheet, Science Advances, 2017
• Mottram, Ruth, et al. “Modelling Glaciers in the HARMONIE-AROME NWP model.” Advances in Science and Research 14 (2017): 323.
• Smith et al, Direct measurements of meltwater runoff on the Greenland ice sheet surface, PNAS, 2017
• Strugnell et al. Dating Antarctic ice sheet collapse: Proposing a molecular genetic approach. Quaternary Science Reviews. 2017
• Madsen et al. Inflated uncertainty in multi‐model based regional climate projections. Geophysical Research Letters. 2017
• Andresen et al. Exceptional 20 th century glaciological regime of a major SE Greenland outlet glacier. Scientific Reports 7, 2017
• Muschitiello et al. Enahnced ice sheet melting driven by volcanic eruptions during the last deglacaitaion, Nature communications, 2017
• Rathmann et al. Highly temporallay resolved response to seasonal surface melt of the zachariae and 79N outlet glaciers in Northeast Greenland, Geophysical Research Letters, 2017
• Mottram et al. Surface mass balance of the Greenland ice sheet in the regional climate model HIRHAM5: Present state and future prospects, Low temperature science, 2017
• Maffezzoli et al. Bromine, iodine and sodium in surface snow along the 2013 Talos Dome–GV7 traverse (northern Victoria Land, East Antarctica) , The Cryosphere, 2017
• Vallelonga et al., Sea-ice-realted halogen enrichment at Law Dome, coastal East Antarctica, Climate of the Past, 2017
• Lang et al., Sea ice thickness and recent Arctic warming, Geophysical Reserach letters, 2017
• Aakeson et al., Simulating the evolution of Hardangerjøkulen ice cap in southern Norway since the mid-Holocene and its sensitivity to climate change, The Cryosphere, 2017
• Slater et al., Spatially distributed runoff at the grounding line of a large Greenlandic tidewater glacier inferred from plume modelling, Journal of Glaciology, 2017
• Smedsrud et al., Fram Strait sea ice export variability and September Arctic sea ice extent over the last 80 years, The Cryosphere, 2017

2016

• Lang et al., Sea ice thickness and recent Arctic warming, Geophysical Research Letters, 2016
• Spolaor et al., Canadian Arctic sea ice reconstructed from bromine in the Greenland NEEM ice core, Nature scientific reports, 2016
• Faber et al. , How does sea ice influence δ18O of Arctic precipitation, Atmos. Chem. Phys., 2016
• Pedersen et al, Greenland during the last interglacial: the relative importance of insolation and oceanic changes, Climate of the past, 2016
• Kjær et al. An Optical Dye Method for Continuous Determination of Acidity in Ice Cores, Env. Sci. & Tech., 2016
• Pedersen et al, The last interglacial climate: comparing direct and indirect impacts of insolation changes, Clim. Dyn, 2016
• Pedro et al. Southern Ocean deep convection as a driver of Antarctic warming events, GRL, 2016
• Ilicak et al., An assessment of the Arctic Ocean in a suite of interannual CORE-II simulations. Part III: Hydrography and fluxes, Ocean modelling, 2016
• Jensen et al., The interaction between sea ice and salinity‑dominated ocean circulation: implications for halocline stability and rapid changes of sea ice cover, Clim. Dyn. 2016
• Spolaor et al., Halogen-based reconstruction of Russian Arctic sea ice area from the Akademii Nauk ice core (Severnaya Zemlya), The cryosphere, 2016
• Philippe et al., Ice core evidence for a 20th century increase in surface mass balance in coastal Dronning Maud Land, East Antarctica, The cryosphere, 2016
• Guo et al., Characteristics of the Nordic Seas overflows in a set of Norwegian Earth System Model experiments, Ocean modelling, 2016
• Pedersen et al., The impact of regional Arctic sea ice loss on atmospheric circulation and the NAO, Journal of Climate, 2016
• Nummelin et al., Consequences of future increased Arctic runoff on Arctic Ocean stratification, circulation, and sea ice cover, JGR. Oceans, 2016

2015

• Kleppin et al., Stochastic Atmospheric Forcing as a Cause of Greenland Climate Transitions, Journal of Climate, 2015