Extreme weather events, which are expected to become more frequent in a warming climate, pose a serious threat to humanity globally. Munich Re, the world’s largest reinsurance company, registered 980 natural catastrophes worldwide in 2020 alone. The five deadliest of these were weather-related. Flash floods and tropical cyclones resulted in more than 1,000 fatalities. In Europe, weather-related extremes caused economic losses averaging 12.5 billion Euros per year over the past decade and the 2003 European heatwave alone led to 70,000 excess deaths. Accurate predictions of weather extremes by the national weather services are indispensable so that preventive actions can be taken by the authorities and the public at an early stage. In particular, pro-active disaster mitigation efforts such as the provisioning of relief goods may take several weeks to implement. Reliable forecasts of the possible occurrence of weather extremes two weeks to two months ahead are therefore of immense value. In addition to such forecasts, reliable predictions on this so-called subseasonal time scale have a considerable socio-economic value for various other sectors. Examples are health, management decisions in agriculture and food security, or efficient planning in the energy sector with its growing share of renewable electricity generation and long-term energy storage systems.
The fundamental challenge of subseasonal forecasts is that, unlike ordinary medium-range weather forecasts that cover at most two weeks, the predictability cannot be gained solely from information on the initial atmospheric state. Due to the chaotic nature of the atmosphere, much of the memory of the atmospheric initial state is lost at this time scale. Further, the subseasonal time scale is yet too short for the slowly changing components of the Earth system, such as the ocean, to contribute significantly to predictability. One approach to account for the associated inherent unpredictability is to perform so-called ensemble forecasts which consider uncertainties in the initial state of the forecast and in the model formulation. These ensemble forecasts, however, become computationally costly especially when being run at a resolution high enough to accurately represent small-scale atmospheric processes. Leveraging recent progress in numerical modelling, machine learning and the availability of large sets of subseasonal weather forecasts, the project aims to reduce the computational costs while at the same time enhance the forecast skill on this time range.If successful, this approach would be a breakthrough towards improved operational weather forecasts at substantially lower computational costs, for a global socio-economic benefit.