High-resolution climate simulation of the last glacial maximum

The climate of the last glacial maximum (LGM) is simulated with a high-resolution atmospheric general circulation model, the NCAR CCM3 at spectral truncation of T170, corresponding to a grid cell size of roughly 75 km. The purpose of the study is to assess whether there are significant benefits from...

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Bibliographic Details
Published in:Climate dynamics 2008-07, Vol.31 (1), p.1-16
Main Authors: Kim, Seong-Joong, Crowley, Thomas J, Erickson, David J, Govindasamy, Bala, Duffy, Phillip B, Lee, Bang Yong
Format: Article
Language:English
Subjects:
ANDES
Atmospheric circulation
Carbon dioxide
Climate change
Climate science
CLIMATES
Climatology
Climatology. Bioclimatology. Climate change
DISTRIBUTION
Earth and Environmental Science
Earth Sciences
Earth, ocean, space
ENVIRONMENTAL SCIENCES
Exact sciences and technology
External geophysics
GENERAL CIRCULATION MODELS
GEOGRAPHY
Geophysics/Geodesy
Glaciers
Ice ages
Marine
Marine and continental quaternary
Meteorology
MONSOONS
MOUNTAINS
Ocean circulation
Oceanography
PHYSICS
PRECIPITATION
RESOLUTION
SALINITY
Sea ice
Sea surface temperature
SEAS
SIMULATION
Surficial geology
TOPOGRAPHY
VALIDATION
Water circulation
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Summary:The climate of the last glacial maximum (LGM) is simulated with a high-resolution atmospheric general circulation model, the NCAR CCM3 at spectral truncation of T170, corresponding to a grid cell size of roughly 75 km. The purpose of the study is to assess whether there are significant benefits from the higher resolution simulation compared to the lower resolution simulation associated with the role of topography. The LGM simulations were forced with modified CLIMAP sea ice distribution and sea surface temperatures (SST) reduced by 1°C, ice sheet topography, reduced CO₂, and 21,000 BP orbital parameters. The high-resolution model captures modern climate reasonably well, in particular the distribution of heavy precipitation in the tropical Pacific. For the ice age case, surface temperature simulated by the high-resolution model agrees better with those of proxy estimates than does the low-resolution model. Despite the fact that tropical SSTs were only 2.1°C less than the control run, there are many lowland tropical land areas 4-6°C colder than present. Comparison of T170 model results with the best constrained proxy temperature estimates (noble gas concentrations in groundwater) now yield no significant differences between model and observations. There are also significant upland temperature changes in the best resolved tropical mountain belt (the Andes). We provisionally attribute this result in part as resulting from decreased lateral mixing between ocean and land in a model with more model grid cells. A longstanding model-data discrepancy therefore appears to be resolved without invoking any unusual model physics. The response of the Asian summer monsoon can also be more clearly linked to local geography in the high-resolution model than in the low-resolution model; this distinction should enable more confident validation of climate proxy data with the high-resolution model. Elsewhere, an inferred salinity increase in the subtropical North Atlantic may have significant implications for ocean circulation changes during the LGM. A large part of the Amazon and Congo Basins are simulated to be substantially drier in the ice age--consistent with many (but not all) paleo data. These results suggest that there are considerable benefits derived from high-resolution model regarding regional climate responses, and that observationalists can now compare their results with models that resolve geography at a resolution comparable to that which the proxy data represen
ISSN:0930-7575
1432-0894
DOI:10.1007/s00382-007-0332-z