Edward C. Wiebe - Abstracts

On the sensitivity of global warming experiments to the parameterisation of sub-grid scale ocean mixing

Wiebe, E.C. and A.J. Weaver

An ocean general circulation model coupled to an energy-moisture balance atmosphere model is used to investigate the sensitivity of global warming experiments to the parameterisation of sub-grid scale ocean mixing. The climate sensitivity of the coupled model using three different parameterisations of sub-grid scale mixing is 3 degrees Celsius for a doubling of CO₂ (6 degrees Celsius for a quadrupling of CO₂). This suggests that the ocean has only a weak feedback on global mean surface air temperature although significant regional differences, notably at high latitudes, exist with different sub-grid scale parameterisations. In the experiment using the Gent and McWilliams parameterisation for mixing associated with mesoscale eddies, an enhancement of the surface response in the Southern Ocean is found. This enhancement is largely due to the existence of more realistic sea-ice in the climatological control integration and the subsequent enhanced ice albedo feedback upon warming. In accordance with earlier analyses, the Gent and McWilliams scheme decreases the global efficiency of ocean heat uptake. During the transient phase of all experiments, the North Atlantic overturning initially weakened but ultimately recovered, surpassing its former strength. This suggests that in the region around the North Atlantic the ocean acts as a negative feedback on local warming during the transient phase but a positive feedback at equilibrium. During the transient phase of the experiments with a more sophisticated and realistic parameterisation of sub-grid scale mixing, warmed Atlantic water was found to penetrate at depth into the Arctic, consistent with recent observations in the region.

Climate Change and Sub-Grid-Scale Mixing in Coupled Model

M. Sc. Thesis Abstract

Global warming experiments are performed using three different versions of an ocean model, coupled to an energy-moisture balance atmosphere model and a thermodynamic ice model. The equilibrium climate sensitivity of the model is 3 degrees Celcius for doubled CO₂ (6 degrees C for quadrupled CO₂) in all experiments. This suggests that the ocean has only a weak feedback on the global mean air temperature. There are, however, significant regional differences, notably at high latitudes, between models with different sub-grid-scale parameterisations. For example, the addition of the Gent and McWilliams parameterisation, of the effects of mesoscale eddies on mixing, results in an enhancement of the surface response in the Southern Ocean. This is largely the consequence of more realistic sea ice in the climatological control integration and subsequent enhancement of the ice-albedo feedback upon warming. During the transient phase of all experiments, the North Atlantic overturning initially weakened but ultimately recovered, surpassing its former strength. This suggests that, in the region around the North Atlantic, the ocean at first acts as a negative feedback on local warming, but contributes a positive feedback at equilibrium. In the transient phase of the experiments with a more sophisticated and realistic parameterisation of sub-grid- scale mixing, warmed Atlantic water was found to penetrate at depth into the Arctic, consistent with recent observations in the region.

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