Abstract
Abstract. General circulation models (GCMs) are valuable tools for understanding how the global ocean–atmosphere–land surface system interacts and are routinely evaluated relative to observational data sets. Conversely, observational data sets can also be used to constrain GCMs in order to identify systematic errors in their simulated climates. One such example is to prescribe sea surface temperatures (SSTs) such that 70 % of the Earth's surface temperature field is observationally constrained (known as an Atmospheric Model Intercomparison Project, AMIP, simulation). Nevertheless, in such simulations, land surface temperatures are typically allowed to vary freely, and therefore any errors that develop over the land may affect the global circulation. In this study therefore, a method for prescribing the land surface temperatures within a GCM (the Australian Community Climate and Earth System Simulator, ACCESS) is presented. Simulations with this prescribed land surface temperature model produce a mean climate state that is comparable to a simulation with freely varying land temperatures; for example, the diurnal cycle of tropical convection is maintained. The model is then developed further to incorporate a selection of “proof of concept” sensitivity experiments where the land surface temperatures are changed globally and regionally. The resulting changes to the global circulation in these sensitivity experiments are found to be consistent with other idealized model experiments described in the wider scientific literature. Finally, a list of other potential applications is described at the end of the study to highlight the usefulness of such a model to the scientific community.
Highlights
In order to minimize circulation errors in general circulation models (GCMs), simulations with prescribed sea surface temperatures (SSTs) from past observations are used
A detailed discussion and physical interpretation of the results shown in Sect. 3 are given in Sect
– The diurnal cycle in tropical convection is maintained in the prescribed simulations
Summary
In order to minimize circulation errors in general circulation models (GCMs), simulations with prescribed sea surface temperatures (SSTs) from past observations are used (for example between 1979 and 2008 as part of the Atmospheric Model Intercomparison Project – AMIP: Gates, 1992; Gates et al, 1999; Taylor et al, 2012). The land surface temperatures are allowed to vary freely in response to the prescribed SST fields in AMIP simulations, which means biases in the representation of surface processes may lead to errors in the simulated atmospheric circulation. Such AMIP experiments have been developed further to include (amongst others) uniform increases of 4 K to the 1979–2008 SST data set and quadrupling carbon-dioxide concentrations with the 1979–2008 SST data (AMIP4K and AMIP4xCO2, respectively – Bony et al, 2011; Taylor et al, 2012); prescribing the land surface temperatures is not routinely done in AMIP experiments. In each of the model experiments that Chadwick et al (2013b), Chou (2003), and Dong and Sutton (2015) undertake, the land surface temperatures are Published by Copernicus Publications on behalf of the European Geosciences Union
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