Using machine learning to parameterize moist convection: potential for modeling of climate, climate change and extreme events

TL;DR

This study demonstrates that machine learning-based moist convection parameterizations, trained on high-resolution data, can be stably integrated into climate models to accurately simulate climate statistics and extreme events, and can adapt to climate change scenarios.

Contribution

It introduces a decision tree-based ML parameterization that ensures conservation laws and effectively captures climate variability and change in GCMs.

Findings

ML parameterization runs stably in GCMs

Accurately captures precipitation extremes

Can simulate climate change effects when trained on multiple climates

Abstract

The parameterization of moist convection contributes to uncertainty in climate modeling and numerical weather prediction. Machine learning (ML) can be used to learn new parameterizations directly from high-resolution model output, but it remains poorly understood how such parameterizations behave when fully coupled in a general circulation model (GCM) and whether they are useful for simulations of climate change or extreme events. Here, we focus on these issues using idealized tests in which an ML-based parameterization is trained on output from a conventional parameterization and its performance is assessed in simulations with a GCM. We use an ensemble of decision trees (random forest) as the ML algorithm, and this has the advantage that it automatically ensures conservation of energy and non-negativity of surface precipitation. The GCM with the ML convective parameterization runs stably and accurately captures important climate statistics including precipitation extremes without the need for special training on extremes. Climate change between a control climate and a warm climate is not captured if the ML parameterization is only trained on the control climate, but it is captured if the training includes samples from both climates. Remarkably, climate change is also captured when training only on the warm climate, and this is because the extratropics of the warm climate provides training samples for the tropics of the control climate. In addition to being potentially useful for the simulation of climate, we show that ML parameterizations can be interrogated to provide diagnostics of the interaction between convection and the large-scale environment.