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This Nature Climate Change review, explores how machine learning can revolutionize climate modeling and analysis to meet growing demands for better projections and actionable climate information. The authors argue that now is the time to advance beyond current techniques by developing more accurate machine-learning-based Earth system models and creating new tools for predicting extreme events, improving detection methods, and enhancing climate model analysis. The review emphasizes the importance of collaboration between machine learning experts and climate scientists, along with the involvement of the private sector, to drive innovation and progress in climate science. **Pierre Gentine** and **Laure Zanna** are co-authors, with works from M²LInES and LEAP heavily featured in the article!
In this [study](https://doi.org/10.1038/s41467-024-51900-x), **Will Gregory** and co-authors **developed an open-source Python library for interpolating sparse altimetry data**, using local Gaussian process models. The library allows them to generate full images of daily sea ice fields at high spatial resolution (5 km), which they hypothesize could be used to train ML models for sub-grid scale parameterizations.
## M²LInES research and other relevant publications
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If you are interested in understanding how M²LInES is using machine learning to improve climate models, we have developed an educational JupyterBook [Learning Machine Learning for Climate modeling with Lorenz 96](https://m2lines.github.io/L96_demo). This JupyterBook describes the key research themes in M²LInES, through the use of a simple climate model and machine learning algorithms. You can run the notebooks yourself, contribute to the development of the JupyterBook or let us know what you think on GitHubhttps://github.com/m2lines/L96_demo.
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If you are interested in understanding how M²LInES is using machine learning to improve climate models, we have developed an educational JupyterBook [Learning Machine Learning for Climate modeling with Lorenz 96](https://m2lines.github.io/L96_demo). This JupyterBook describes the key research themes in M²LInES, through the use of a simple climate model and machine learning algorithms. You can run the notebooks yourself, contribute to the development of the JupyterBook or let us know what you think on GitHub.
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<imgsrc="/images/newlogo.png"style="width: 1.5vw; height: 1.5hw; vertical-align: middle;"alt="DOI icon"> M²LInES funded research
<strong>William Gregory, Ronald MacEachern, So Takao, Isobel R. Lawrence, Carmen Nab, Marc Peter Deisenroth, Michel Tsamados </strong><br>
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<a href="https://doi.org/10.1038/s41467-024-51900-x" target="_blank"><strong>Scalable interpolation of satellite altimetry data with probabilistic machine learning</strong></a><br>
<a href="https://doi.org/10.1038/s41558-024-02095-y" target="_blank"><strong>SPushing the frontiers in climate modelling and analysis with machine learning</strong></a><br>
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