Abstract
Abstract. The Absolute Regional Temperature Potential (ARTP) is one of the few climate metrics that provides estimates of impacts at a sub-global scale. The ARTP presented here gives the time-dependent temperature response in four latitude bands (90–28° S, 28° S–28° N, 28–60° N and 60–90° N) as a function of emissions based on the forcing in those bands caused by the emissions. It is based on a large set of simulations performed with a single atmosphere-ocean climate model to derive regional forcing/response relationships. Here I evaluate the robustness of those relationships using the forcing/response portion of the ARTP to estimate regional temperature responses to the historic aerosol forcing in three independent climate models. These ARTP results are in good accord with the actual responses in those models. Nearly all ARTP estimates fall within ±20% of the actual responses, though there are some exceptions for 90–28° S and the Arctic, and in the latter the ARTP may vary with forcing agent. However, for the tropics and the Northern Hemisphere mid-latitudes in particular, the ±20% range appears to be roughly consistent with the 95% confidence interval. Land areas within these two bands respond 39–45% and 9–39% more than the latitude band as a whole. The ARTP, presented here in a slightly revised form, thus appears to provide a relatively robust estimate for the responses of large-scale latitude bands and land areas within those bands to inhomogeneous radiative forcing and thus potentially to emissions as well. Hence this metric could allow rapid evaluation of the effects of emissions policies at a finer scale than global metrics without requiring use of a full climate model.
Highlights
The Absolute Regional Temperature Potential (ARTP) is an emission metric that provides estimates of regional surface temperature responses to emissions accounting for the regional radiative forcings (RFs) caused by the emissions
The global mean sensitivities are used for ARTP calculations for each model: 0.90 K per W m−2 for Geophysical Fluid Dynamics Laboratory (GFDL), 0.89 K per W m−2 for Institute Pierre Simon Laplace (IPSL), 1.10 K per W m−2 for SPRINTARS, and 0.50 K per W m−2 for Goddard Institute for Space Studies (GISS)
Aside from the GISS model, these values are similar to the 1.06 K per W m−2 long-term response embodied in the IRF based on the Hadley Centre model in the time-varying ARTP
Summary
The ARTP is an emission metric that provides estimates of regional surface temperature responses to emissions accounting for the regional radiative forcings (RFs) caused by the emissions. The ARTP is an analogue of the absolute global temperature potential (AGTP), which provides an estimate of the global mean temperature response to a given emission based on that emission’s global mean RF as a function of time (Shine et al, 2005b). Emission metrics such as these are widely used in analysis of the temperature impacts of emission scenarios or mitigation policies and in emissions trading systems. I present an evaluation of the robustness of the forcing/response relationships used in the ARTP based on independent climate models. Shindell et al.: Evaluation of the absolute regional temperature potential
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