Temperature trends during the Present and Last Interglacial periods - a multi-model-data comparison

Though primarily driven by insolation changes associated with well-known variations in Earth's astronomical parameters, the response of the climate system during interglacials includes a diversity of feedbacks involving the atmosphere, ocean, sea ice, vegetation and land ice. A thorough multimo...

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Bibliographic Details
Published in:Quaternary Science Reviews
Main Authors: P. Bakker, V. Masson Delmotte, B. Martrat, S. Charbit, H. Renssen, M. Gröger, U. Krebs Kanzow, G. Lohman, D. J. Lunt, M. Pfeiffer, S. J. Phipps, M. Prange, S. P. Ritz, M. Schulz, E. J. Stone, V. Varma, STENNI, Barbara
Other Authors: P., Bakker, V., Masson Delmotte, B., Martrat, S., Charbit, H., Renssen, M., Gröger, U., Krebs Kanzow, G., Lohman, D. J., Lunt, M., Pfeiffer, S. J., Phipp, M., Prange, S. P., Ritz, M., Schulz, Stenni, Barbara, E. J., Stone, V., Varma
Format: Article in Journal/Newspaper
Language:English
Published: 2014
Subjects:
Palaeoclimatology
Interglacial
Modelling
Reconstruction
Model-data comparison
Temperature
Greenland
Antarc*
Antarctica
Greenland ice cores
ice core
Sea ice
Online Access:http://hdl.handle.net/10278/42738
https://doi.org/10.1016/j.quascirev.2014.06.031
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Summary:Though primarily driven by insolation changes associated with well-known variations in Earth's astronomical parameters, the response of the climate system during interglacials includes a diversity of feedbacks involving the atmosphere, ocean, sea ice, vegetation and land ice. A thorough multimodel- data comparison is essential to assess the ability of climate models to resolve interglacial temperature trends and to help in understanding the recorded climatic signal and the underlying climate dynamics. We present the first multi-model-data comparison of transient millennial-scale temperature changes through two intervals of the Present Interglacial (PIG; 8-1.2 ka) and the Last Interglacial (LIG; 123-116.2 ka) periods. We include temperature trends simulated by 9 different climate models, alkenone-based temperature reconstructions from 117 globally distributed locations (about 45% of them within the LIG) and 12 ice-core-based temperature trends from Greenland and Antarctica (50% of them within the LIG). The definitions of these specific interglacial intervals enable a consistent inter-comparison of the two intervals because both are characterised by minor changes in atmospheric greenhouse gas concentrations and more importantly by insolation trends that show clear similarities. Our analysis shows that in general the reconstructed PIG and LIG Northern Hemisphere mid-to-high latitude cooling compares well with multi-model, mean-temperature trends for the warmest months and that these cooling trends reflect a linear response to the warmest-month insolation decrease over the interglacial intervals. The most notable exception is the strong LIG cooling trend reconstructed from Greenland ice cores that is not simulated by any of the models. A striking model-data mismatch is found for both the PIG and the LIG over large parts of the mid-to-high latitudes of the Southern Hemisphere where the data depicts negative temperature trends that are not in agreement with near zero trends in the simulations. In this area, the ...

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