Abstract
Abstract. Future sea surface temperature and sea-ice concentration from coupled ocean–atmosphere general circulation models such as those from the CMIP5 experiment are often used as boundary forcings for the downscaling of future climate experiments. Yet, these models show some considerable biases when compared to the observations over present climate. In this paper, existing methods such as an absolute anomaly method and a quantile–quantile method for sea surface temperature (SST) as well as a look-up table and a relative anomaly method for sea-ice concentration (SIC) are presented. For SIC, we also propose a new analogue method. Each method is objectively evaluated with a perfect model test using CMIP5 model experiments and some real-case applications using observations. We find that with respect to other previously existing methods, the analogue method is a substantial improvement for the bias correction of future SIC. Consistency between the constructed SST and SIC fields is an important constraint to consider, as is consistency between the prescribed sea-ice concentration and thickness; we show that the latter can be ensured by using a simple parameterisation of sea-ice thickness as a function of instantaneous and annual minimum SIC.
Highlights
Introduction and contextCoupled climate models are the most reliable tools that we have today for large-scale climate projections, such as in the Coupled Model Intercomparison Project Phase 5 (CMIP5; Taylor et al, 2012)
The utility of a perfect model test here is limited for sea surface temperatures (SST), and it was only applied in order to be consistent with the evaluation of the method for sea-ice concentration (SIC)
We reviewed existing methods for the bias correction of SST and SIC and proposed new ones, such as the analogue method for sea ice
Summary
Coupled climate models are the most reliable tools that we have today for large-scale climate projections, such as in the Coupled Model Intercomparison Project Phase 5 (CMIP5; Taylor et al, 2012). Giorgi and Gutowski, 2016) or highresolution atmospheric global circulation models (Haarsma et al, 2016). In both cases, information about the projected changes in sea surface conditions, such as sea surface temperatures (SST), sea-ice concentration (SIC) and sea-ice thickness (SIT), is required as a lower boundary condition for the higher-resolution models. The validity and reliability of such coupled simulations is questionable for future climate projections (e.g. the end of the 21st century), and so is their use as boundary conditions when performing dynamical downscaling of future climate projections
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