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Main Authors: Kent, Chris, Scaife, Adam A., Dunstone, Nick J., Smith, Doug, Hardiman, Steven C., Dunstan, Tom, Watt-Meyer, Oliver
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.23953
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author Kent, Chris
Scaife, Adam A.
Dunstone, Nick J.
Smith, Doug
Hardiman, Steven C.
Dunstan, Tom
Watt-Meyer, Oliver
author_facet Kent, Chris
Scaife, Adam A.
Dunstone, Nick J.
Smith, Doug
Hardiman, Steven C.
Dunstan, Tom
Watt-Meyer, Oliver
contents Machine learning weather models trained on observed atmospheric conditions can outperform conventional physics-based models at short- to medium-range (1-14 day) forecast timescales. Here we take the machine learning weather model ACE2, trained to predict 6-hourly steps in atmospheric evolution and which can remain stable over long forecast periods, and assess it from a seasonal forecasting perspective. Applying persisted sea surface temperature (SST) and sea-ice anomalies centred on 1st November each year, we initialise a lagged ensemble of winter predictions covering 1993/1994 to 2015/2016. Over this 23-year period there is remarkable similarity in the patterns of predictability with a leading physics-based model. The ACE2 model exhibits skilful predictions of the North Atlantic Oscillation (NAO) with a correlation score of 0.47 (p=0.02), as well as a realistic global distribution of skill and ensemble spread. Surprisingly, ACE2 is found to exhibit a signal-to-noise error as seen in physics-based models, in which it is better at predicting the real world than itself. Examining predictions of winter 2009/2010 indicates potential limitations of ACE2 in capturing extreme seasonal conditions that extend outside the training data. Nevertheless, this study reveals that machine learning weather models can produce skilful global seasonal predictions and heralds a new era of increased understanding, development and generation of near-term climate predictions.
format Preprint
id arxiv_https___arxiv_org_abs_2503_23953
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Skilful global seasonal predictions from a machine learning weather model trained on reanalysis data
Kent, Chris
Scaife, Adam A.
Dunstone, Nick J.
Smith, Doug
Hardiman, Steven C.
Dunstan, Tom
Watt-Meyer, Oliver
Atmospheric and Oceanic Physics
Machine learning weather models trained on observed atmospheric conditions can outperform conventional physics-based models at short- to medium-range (1-14 day) forecast timescales. Here we take the machine learning weather model ACE2, trained to predict 6-hourly steps in atmospheric evolution and which can remain stable over long forecast periods, and assess it from a seasonal forecasting perspective. Applying persisted sea surface temperature (SST) and sea-ice anomalies centred on 1st November each year, we initialise a lagged ensemble of winter predictions covering 1993/1994 to 2015/2016. Over this 23-year period there is remarkable similarity in the patterns of predictability with a leading physics-based model. The ACE2 model exhibits skilful predictions of the North Atlantic Oscillation (NAO) with a correlation score of 0.47 (p=0.02), as well as a realistic global distribution of skill and ensemble spread. Surprisingly, ACE2 is found to exhibit a signal-to-noise error as seen in physics-based models, in which it is better at predicting the real world than itself. Examining predictions of winter 2009/2010 indicates potential limitations of ACE2 in capturing extreme seasonal conditions that extend outside the training data. Nevertheless, this study reveals that machine learning weather models can produce skilful global seasonal predictions and heralds a new era of increased understanding, development and generation of near-term climate predictions.
title Skilful global seasonal predictions from a machine learning weather model trained on reanalysis data
topic Atmospheric and Oceanic Physics
url https://arxiv.org/abs/2503.23953