Abstract
AbstractClimate models exhibit a broad range in the simulated properties of the climate system. In the early historical period, the absolute global mean surface air temperature in Coupled Model Intercomparison Project, Phase 5 (CMIP5) models spans a range of ∼12°C – 15°C. Other climate variables may be linked to global mean temperature, and so accurate representation of the baseline climate state is crucial for meaningful future climate projections. In CMIP5 baseline climate states, statistically significant intermodel correlations between Southern Ocean surface temperature, outgoing shortwave radiation, cloudiness, the position of the mid‐latitude eddy‐driven jet, and Antarctic sea ice area are found. The baseline temperature relationships extend to projected future changes in the same set of variables, impacting on the projected global mean surface temperature change. Models with initially cooler Southern Ocean tend to exhibit more global warming, and vice versa for initially warmer models. These relationships arise due to a “capacity for change”. For example, cold‐biased models tend to have more cloud cover, sea ice, and equatorward jet initially, and thus a greater capacity to lose cloud cover and sea ice, and for the jet to shift poleward under global warming. A first look at emerging data from CMIP6 reveals a shift of the relationship from the Southern Ocean towards the Antarctic region, possibly due to reductions in Southern Ocean biases, such as in westerly wind representation.
Highlights
Gauging the sensitivity of the Earth's climate to greenhouse gas forcing is crucial for efforts to mitigating the risks of human-induced climate change
Motivated by the emergent constraints approach, and utilizing the complete suite of CMIP5 simulations, we aim to explore the possible role of baseline biases in the Southern Ocean system in CMIP5, and their impact on projected changes, locally and globally
The relationships for the baseline state are physically consistent, that is, with warmer Southern Ocean there is a tendency for less cloud, and less TOA outgoing shortwave radiation, less sea ice and a more poleward eddy-driven jet (Figure 10a)
Summary
Gauging the sensitivity of the Earth's climate to greenhouse gas forcing is crucial for efforts to mitigating the risks of human-induced climate change. The Earth's climate sensitivity remains highly uncertain. The most typical measure, equilibrium climate sensitivity (ECS), is defined as the global temperature change in response to a doubling to atmospheric CO2. The Intergovernmental Panel on Climate Change estimated a likely range in ECS of 1.5°C – 4.5°C in the Fifth Assessment Report (AR5; Stocker et al, 2013). A more recent review, using multiple lines of evidence, narrowed the range to 2.6°C – 3.9°C (Sherwood et al, 2020).
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