Your search keyword '"Haywood, Alan M"' showing total 3 results

1. Highly restricted near‐surface permafrost extent during the mid-Pliocene warm period.

Author

Donglin Guo, Huijun Wang, Romanovsky, Vladimir E., Haywood, Alan M., Pepin, Nick, Salzmann, Ulrich, Jianqi Sun, Qing Yan, Zhongshi Zhang, Xiangyu Li, Otto-Bliesner, Bette L., Ran Feng, Lohmann, Gerrit, Stepanek, Christian, Ayako Abe-Ouchi, Wing-Le Chan, Peltier, W. Richard, Chandan, Deepak, von der Heydt, Anna S., and Contoux, Camille

Subjects

PERMAFROST, SURFACE temperature, ATMOSPHERIC temperature, UPLANDS, PLIOCENE Epoch

Abstract

Accurate understanding of permafrost dynamics is critical for evaluating and mitigating impacts that may arise as permafrost degrades in the future; however, existing projections have large uncertainties. Studies of how permafrost responded historically during Earth’s past warm periods are helpful in exploring potential future permafrost behavior and to evaluate the uncertainty of future permafrost change projections. Here, we combine a surface frost index model with outputs from the second phase of the Pliocene Model Intercomparison Project to simulate the near‐surface (~3 to 4 m depth) permafrost state in the Northern Hemisphere during the mid-Pliocene warm period (mPWP, ~3.264 to 3.025 Ma). This period shares similarities with the projected future climate. Constrained by proxy-based surface air temperature records, our simulations demonstrate that near‐surface permafrost was highly spatially restricted during the mPWP and was 93 ± 3% smaller than the preindustrial extent. Near‐surface permafrost was present only in the eastern Siberian uplands, Canadian high Arctic Archipelago, and northernmost Greenland. The simulations are similar to near‐surface permafrost changes projected for the end of this century under the SSP5-8.5 scenario and provide a perspective on the potential permafrost behavior that may be expected in a warmer world. [ABSTRACT FROM AUTHOR]

Published

2023

2. Late Pliocene Greenland glaciation controlled by a decline in atmospheric CO2 levels.

Author

Lunt, Daniel J., Foster, Gavin L., Haywood, Alan M., and Stone, Emma J.

Subjects

GLACIERS, ICE sheets, ATMOSPHERIC carbon dioxide, GENERAL circulation model, EL Nino, ATMOSPHERIC chemistry, PLIOCENE stratigraphic geology

Abstract

It is thought that the Northern Hemisphere experienced only ephemeral glaciations from the Late Eocene to the Early Pliocene epochs (about 38 to 4 million years ago), and that the onset of extensive glaciations did not occur until about 3 million years ago. Several hypotheses have been proposed to explain this increase in Northern Hemisphere glaciation during the Late Pliocene. Here we use a fully coupled atmosphere–ocean general circulation model and an ice-sheet model to assess the impact of the proposed driving mechanisms for glaciation and the influence of orbital variations on the development of the Greenland ice sheet in particular. We find that Greenland glaciation is mainly controlled by a decrease in atmospheric carbon dioxide during the Late Pliocene. By contrast, our model results suggest that climatic shifts associated with the tectonically driven closure of the Panama seaway, with the termination of a permanent El Niño state or with tectonic uplift are not large enough to contribute significantly to the growth of the Greenland ice sheet; moreover, we find that none of these processes acted as a priming mechanism for glacial inception triggered by variations in the Earth’s orbit. [ABSTRACT FROM AUTHOR]

Published

2008

3. Late Pliocene Greenland glaciation controlled by a decline in atmospheric CO2 levels.

Author

Lunt DJ, Foster GL, Haywood AM, and Stone EJ

Subjects

Carbon Dioxide analysis, Climate, Greenland, History, Ancient, North America, Rain, Time Factors, Atmosphere chemistry, Carbon Dioxide metabolism, Ice Cover

Abstract

It is thought that the Northern Hemisphere experienced only ephemeral glaciations from the Late Eocene to the Early Pliocene epochs (about 38 to 4 million years ago), and that the onset of extensive glaciations did not occur until about 3 million years ago. Several hypotheses have been proposed to explain this increase in Northern Hemisphere glaciation during the Late Pliocene. Here we use a fully coupled atmosphere-ocean general circulation model and an ice-sheet model to assess the impact of the proposed driving mechanisms for glaciation and the influence of orbital variations on the development of the Greenland ice sheet in particular. We find that Greenland glaciation is mainly controlled by a decrease in atmospheric carbon dioxide during the Late Pliocene. By contrast, our model results suggest that climatic shifts associated with the tectonically driven closure of the Panama seaway, with the termination of a permanent El Niño state or with tectonic uplift are not large enough to contribute significantly to the growth of the Greenland ice sheet; moreover, we find that none of these processes acted as a priming mechanism for glacial inception triggered by variations in the Earth's orbit.

Published

2008