Detection and Attribution of Regional Climate Change

We developed a high resolution global coupled modeling capability to perform breakthrough studies of the regional climate change. The atmospheric component in our simulation uses a 1{sup o} latitude x 1.25{sup o} longitude grid which is the finest resolution ever used for the NCAR coupled climate mo...

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Bibliographic Details
Main Authors: Bala, G., Mirin, A.
Other Authors: United States. Department of Energy.
Format: Report
Language:English
Published: Lawrence Livermore National Laboratory 2007
Subjects:
Lawrence Livermore National Laboratory
Testing
Oceanography
Validation
Seas
Thickness
58 Geosciences
Detection
54 Environmental Sciences
Configuration
Simulation
Distribution
Resolution
Climate Models
Climates
Antarctic
Arctic
Scripps
The Antarctic
Antarc*
Climate change
Sea ice
Online Access:https://doi.org/10.2172/1036845
https://digital.library.unt.edu/ark:/67531/metadc834490/
Description
Summary:We developed a high resolution global coupled modeling capability to perform breakthrough studies of the regional climate change. The atmospheric component in our simulation uses a 1{sup o} latitude x 1.25{sup o} longitude grid which is the finest resolution ever used for the NCAR coupled climate model CCSM3. Substantial testing and slight retuning was required to get an acceptable control simulation. The major accomplishment is the validation of this new high resolution configuration of CCSM3. There are major improvements in our simulation of the surface wind stress and sea ice thickness distribution in the Arctic. Surface wind stress and ocean circulation in the Antarctic Circumpolar Current are also improved. Our results demonstrate that the FV version of the CCSM coupled model is a state of the art climate model whose simulation capabilities are in the class of those used for IPCC assessments. We have also provided 1000 years of model data to Scripps Institution of Oceanography to estimate the natural variability of stream flow in California. In the future, our global model simulations will provide boundary data to high-resolution mesoscale model that will be used at LLNL. The mesoscale model would dynamically downscale the GCM climate to regional scale on climate time scales.

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