Mikolajewicz, Uwe (2011): Regional ocean model for the Mediterranean, links to model files [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.758224, Supplement to: Mikolajewicz, U (2011): Modeling Mediterranean Ocean climate of the Last Glacial Maximum. Climate of the Past, 7, 161-180, https://doi.org/10.5194/cp-7-161-2011
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Abstract:
A regional ocean general circulation model of the Mediterranean is used to study the climate of the Last Glacial Maximum. The atmospheric forcing for these simulations has been derived from simulations with an atmospheric general circulation model, which in turn was forced with surface conditions from a coarse resolution earth system model. The model is successful in reproducing the general patterns of reconstructed sea surface temperature anomalies with the strongest cooling in summer in the northwestern Mediterranean and weak cooling in the Levantine, although the model underestimates the extent of the summer cooling in the western Mediterranean. However, there is a strong vertical gradient associated with this pattern of summer cooling, which makes the comparison with reconstructions complicated. The exchange with the Atlantic is decreased to roughly one half of its present value, which can be explained by the shallower Strait of Gibraltar as a consequence of lower global sea level. This reduced exchange causes a strong increase of salinity in the Mediterranean in spite of reduced net evaporation.
Project(s):
Integrierte Analyse zwischeneiszeitlicher Klimadynamik (INTERDYNAMIK)
Funding:
German Research Foundation (DFG), grant/award no. 25575884: Integrierte Analyse zwischeneiszeitlicher Klimadynamik
Comment:
Climatologies calculated from last 100 model years.This publication and supplement is a result of sub-project "Holocene climate dynamics and biogeochemical cycles in the Mediterranean Sea" (HOBIMED, web page archived at hdl:10013/epic.37022.d001).
Parameter(s):
License:
Creative Commons Attribution 3.0 Unported (CC-BY-3.0)
Size:
56 data points
Data
1 File name | 2 Exp | 3 Parameter | 4 Unit | 5 URL model | 6 File size [kByte] | 7 File format |
---|---|---|---|---|---|---|
so_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | LGM (last glacial maximum) | so - salinity | [psu] | so_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | 4300 | NetCDF, gzip compressed |
so_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | piControl (preindustrial control, called CTL in the paper) | so - salinity | [psu] | so_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | 5600 | NetCDF, gzip compressed |
thetao_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | LGM (last glacial maximum) | thetao - potential temperature | [K] | thetao_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | 4300 | NetCDF, gzip compressed |
thetao_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | piControl (preindustrial control, called CTL in the paper) | thetao - potential temperature | [K] | thetao_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | 5300 | NetCDF, gzip compressed |
uo_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | LGM (last glacial maximum) | model E-W component of horizontal velocity | [m/sec] | uo_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | 5400 | NetCDF, gzip compressed |
uo_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | piControl (preindustrial control, called CTL in the paper) | model E-W component of horizontal velocity | [m/sec] | uo_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | 6800 | NetCDF, gzip compressed |
vo_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | LGM (last glacial maximum) | model N-S component of horizontal velocity | [m/sec] | vo_Omon_MPIOM-MR_lgm_r1i1p1_209901-209912.nc.gz | 5400 | NetCDF, gzip compressed |
vo_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | piControl (preindustrial control, called CTL in the paper) | model N-S component of horizontal velocity | [m/sec] | vo_Omon_MPIOM-MR_piControl_r1i1p1_199901-199912.nc.gz | 6700 | NetCDF, gzip compressed |