Environmental systems are characterized by high-dimensional, non-linear interactions across atmospheric, hydrological, and terrestrial domains. Traditional mechanistic models, while robust in theory, often struggle with the sheer scale and noise of modern sensor data, frequently falling victim to "parameterization lag" where sub-grid processes—such as convective cloud formation, localized turbulence, or soil-canopy moisture exchange—are oversimplified into static coefficients. This article explores the paradigm shift toward machine learning (ML) for interpreting complex environmental dynamics. We present a multi-scale framework utilizing Convolutional Long Short-Term Memory (ConvLSTM) networks for capturing spatial-temporal fluid dynamics and Random Forests for high-resolution terrestrial feature importance. Furthermore, we address the "black box" nature of these models using SHapley Additive exPlanations (SHAP) to bridge the gap between statistical correlation and physical causality. Our results demonstrate a 15-22% improvement in predictive accuracy for localized weather events and air quality fluctuations compared to standard numerical weather prediction (NWP) models, offering a scalable path toward enhanced climate resilience, precision agriculture, and real-time disaster mitigation.
Mitchell et al. (Wed,) studied this question.