Abstract
Seasonal forecasts using coupled ocean–atmosphere climate models are increasingly employed to provide regional climate predictions. For the quality of forecasts to improve, regional biases in climate models must be diagnosed and reduced. The evolution of biases as initialized forecasts drift away from the observations is poorly understood, making it difficult to diagnose the causes of climate model biases. This study uses two seasonal forecast systems to examine drifts in sea surface temperature (SST) and precipitation, and compares them to the long-term bias in the free-running version of each model. Drifts are considered from daily to multi-annual time scales. We define three types of drift according to their relation with the long-term bias in the free-running model: asymptoting, overshooting and inverse drift. We find that precipitation almost always has an asymptoting drift. SST drifts on the other hand, vary between forecasting systems, where one often overshoots and the other often has an inverse drift. We find that some drifts evolve too slowly to have an impact on seasonal forecasts, even though they are important for climate projections. The bias found over the first few days can be very different from that in the free-running model, so although daily weather predictions can sometimes provide useful information on the causes of climate biases, this is not always the case. We also find that the magnitude of equatorial SST drifts, both in the Pacific and other ocean basins, depends on the El Niño Southern Oscillation (ENSO) phase. Averaging over all hindcast years can therefore hide the details of ENSO state dependent drifts and obscure the underlying physical causes. Our results highlight the need to consider biases across a range of timescales in order to understand their causes and develop improved climate models.
Highlights
It is essential to reduce model biases and improve the representation of underlying physical processes to achieve credible regional information in climate projections (Xie et al 2015)
We investigate the development of model biases relevant to seasonal to decadal forecasts using two operational seasonal forecast systems, those of the Beijing Climate Center and the Met Office
In December–January–February (DJF) the global mean sea surface temperature (SST) bias for Beijing Climate Center (BCC) is −0.4 K and the northern and southern hemispheres have a bias of − 1.1 and 0.1 K, respectively
Summary
It is essential to reduce model biases and improve the representation of underlying physical processes to achieve credible regional information in climate projections (Xie et al 2015). 3 we first compare drifts in seasonal to decadal forecasts with the long-term biases of the free-running versions of the same models for sea surface temperature (SST) and precipitation over a number of regions where known model problems exist. To complement GloSea and provide some information on multi-annual model drifts we use the Met Office Decadal Prediction System version 3 (DePreSys3) described in Dunstone et al (2016), which is initialized only on 1 November for 26 start dates between 1960 and 2014. To evaluate precipitation we use the same 30 years of GPCP V2.2 Combined Precipitation data set (Adler et al 2003)
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