Your search keyword '"Behrens, L. K."' showing total 7 results

1. Arctic sea ice area changes in CMIP3 and CMIP5 climate models’ ensembles

Author

Semenov, V. A., Martin, Thomas, Behrens, L. K., Latif, Mojib, Astafieva, E. S., Semenov, V. A., Martin, Thomas, Behrens, L. K., Latif, Mojib, and Astafieva, E. S.

Abstract

The shrinking Arctic sea ice cover observed during the last decades is probably the clearest manifestation of ongoing climate change. While climate models in general reproduce the sea ice retreat in the Arctic during the 20th century and simulate further sea ice area loss during the 21st century in response to anthropogenic forcing, the models suffer from large biases and the results exhibit considerable spread. Here, we compare results from the two last generations of climate models, CMIP3 and CMIP5, with respect to total and regional Arctic sea ice change. Different characteristics of sea ice area (SIA) in March and September have been analysed for the Entire Arctic, Central Arctic and Barents Sea. Further, the sensitivity of SIA to changes in Northern Hemisphere (NH) temperature is investigated and dynamical links between SIA and some atmospheric variability modes are assessed. CMIP3 (SRES A1B) and CMIP5 (RCP8.5) models not only simulate a coherent decline of the Arctic SIA but also depict consistent changes in the SIA seasonal cycle. The spatial patterns of SIC variability improve in CMIP5 ensemble, most noticeably in summer when compared to HadISST1 data. A better simulation of summer SIA in the Entire Arctic by CMIP5 models is accompanied by a slightly increased bias for winter season in comparison to CMIP3 ensemble. SIA in the Barents Sea is strongly overestimated by the majority of CMIP3 and CMIP5 models, and projected SIA changes are characterized by a high uncertainty. Both CMIP ensembles depict a significant link between the SIA and NH temperature changes indicating that a part of inter-ensemble SIA spread comes from different temperature sensitivity to anthropogenic forcing. The results suggest that, in general, a sensitivity of SIA to external forcing is enhanced in CMIP5 models. Arctic SIA interannual variability in the end of the 20th century is on average well simulated by both ensembles. To the end of the 21st century, September variability is stron

Published

2017

2. Arctic sea ice area changes in CMIP3 and CMIP5 climate models’ ensembles

Author

Semenov, V. A., primary, Martin, T., additional, Behrens, L. K., additional, Latif, M., additional, and Astafieva, E. S., additional

Published

2017

3. Arctic sea ice area in CMIP3 and CMIP5 climate model ensembles – variability and change

Author

Semenov, Vladimir A., Martin, Thomas, Behrens, L. K., Latif, Mojib, Semenov, Vladimir A., Martin, Thomas, Behrens, L. K., and Latif, Mojib

Abstract

The shrinking Arctic sea ice cover observed during the last decades is probably the clearest manifestation of ongoing climate change. While climate models in general reproduce the sea ice retreat in the Arctic during the 20th century and simulate further sea ice area loss during the 21st century in response to anthropogenic forcing, the models suffer from large biases and the model results exhibit considerable spread. The last generation of climate models from World Climate Research Programme Coupled Model Intercomparison Project Phase 5 (CMIP5), when compared to the previous CMIP3 model ensemble and considering the whole Arctic, were found to be more consistent with the observed changes in sea ice extent during the recent decades. Some CMIP5 models project strongly accelerated (non-linear) sea ice loss during the first half of the 21st century. Here, complementary to previous studies, we compare results from CMIP3 and CMIP5 with respect to regional Arctic sea ice change. We focus on September and March sea ice. Sea ice area (SIA) variability, sea ice concentration (SIC) variability, and characteristics of the SIA seasonal cycle and interannual variability have been analysed for the whole Arctic, termed Entire Arctic, Central Arctic and Barents Sea. Further, the sensitivity of SIA changes to changes in Northern Hemisphere (NH) averaged temperature is investigated and several important dynamical links between SIA and natural climate variability involving the Atlantic Meridional Overturning Circulation (AMOC), North Atlantic Oscillation (NAO) and sea level pressure gradient (SLPG) in the western Barents Sea opening serving as an index of oceanic inflow to the Barents Sea are studied. The CMIP3 and CMIP5 models not only simulate a coherent decline of the Arctic SIA but also depict consistent changes in the SIA seasonal cycle and in the aforementioned dynamical links. The spatial patterns of SIC variability improve in the CMIP5 ensemble, particularly in summer. Both CMI

Published

2015

4. Seasonal evolution of an ice-shelf influenced fast-ice regime, derived from an autonomous thermistor chain

Author

Hoppmann, M., primary, Nicolaus, M., additional, Hunkeler, P. A., additional, Heil, P., additional, Behrens, L.-K., additional, König-Langlo, G., additional, and Gerdes, R., additional

Published

2015

5. Arctic sea ice area in CMIP3 and CMIP5 climate model ensembles – variability and change

Author

Semenov, V. A., primary, Martin, T., additional, Behrens, L. K., additional, and Latif, M., additional

Published

2015

6. The Arctic Sea ice in the CMIP3 climate model ensemble – variability and anthropogenic change

Author

Behrens, L. K., Martin, Thomas, Semenov, Vladimir, Latif, Mojib, Behrens, L. K., Martin, Thomas, Semenov, Vladimir, and Latif, Mojib

Abstract

The strongest manifestation of global warming is observed in the Arctic. The warming in the Arctic during the recent decades is about twice as strong as in the global average and has been accompanied by a summer sea ice decline that is very likely unprecedented during the last millennium. Here, Arctic sea ice variability is analyzed in the ensemble of CMIP3 models. Complementary to several previous studies, we focus on regional aspects, in particular on the Barents Sea. We also investigate the changes in the seasonal cycle and interannual variability. In all regions, the models predict a reduction in sea ice area and sea ice volume during 1900–2100. Toward the end of the 21st century, the models simulate higher sea ice area variability in September than in March, whereas the variability in the preindustrial control runs is higher in March. Furthermore, the amplitude and phase of the sea ice seasonal cycle change in response to enhanced greenhouse warming. The amplitude of the sea ice area seasonal cycle increases due to the very strong sea ice area decline in September. The seasonal cycle amplitude of the sea ice volume decreases due to the stronger reduction of sea ice volume in March. Multi-model mean estimates for the late 20th century are comparable with observational data only for the entire Arctic and the Central Arctic. In the Barents Sea, differences between the multi-model mean and the observational data are more pronounced. Regional sea ice sensitivity to Northern Hemisphere average surface warming has been investigated.

Published

2012

7. The Arctic Sea ice in the CMIP3 climate model ensemble – variability and anthropogenic change

Author

Behrens, L. K., primary, Martin, T., additional, Semenov, V. A., additional, and Latif, M., additional

Published

2012