@Article{Espeholt2022,
author={Espeholt, Lasse
and Agrawal, Shreya
and S{\o}nderby, Casper
and Kumar, Manoj
and Heek, Jonathan
and Bromberg, Carla
and Gazen, Cenk
and Carver, Rob
and Andrychowicz, Marcin
and Hickey, Jason
and Bell, Aaron
and Kalchbrenner, Nal},
title={Deep learning for twelve hour precipitation forecasts},
journal={Nature Communications},
year={2022},
month={Sep},
day={01},
volume={13},
number={1},
pages={5145},
abstract={Existing weather forecasting models are based on physics and use supercomputers to evolve the atmosphere into the future. Better physics-based forecasts require improved atmospheric models, which can be difficult to discover and develop, or increasing the resolution underlying the simulation, which can be computationally prohibitive. An emerging class of weather models based on neural networks overcome these limitations by learning the required transformations from data instead of relying on hand-coded physics and by running efficiently in parallel. Here we present a neural network capable of predicting precipitation at a high resolution up to 12{\thinspace}h ahead. The model predicts raw precipitation targets and outperforms for up to 12{\thinspace}h of lead time state-of-the-art physics-based models currently operating in the Continental United States. The results represent a substantial step towards validating the new class of neural weather models.},
issn={2041-1723},
doi={10.1038/s41467-022-32483-x},
url={https://doi.org/10.1038/s41467-022-32483-x}
}