Tracking Low-Level Cloud Systems with Topology

Low-level clouds are ubiquitous in Earth’s atmosphere. Their response to atmospheric conditions are essential to understanding the climate system and its sensitivity to anthropogenic influences. High-resolution geostationary satellites now resolve cloud systems with unprecedented detail, promoting cloud tracking as a vital research area for studying their spatiotemporal dynamics. It enables disentangling advective and convective components driving cloud evolution. This, in turn, provides deeper insights into the structure and lifecycle of low-level cloud systems and the atmospheric processes that govern them. In this paper, we propose a novel framework for tracking cloud systems using topology-driven techniques based on optimal transport. We first obtain a set of anchor points for the cloud systems based on the merge tree of the cloud optical depth field. We then apply topology-driven probabilistic feature tracking of these anchor points to guide the tracking of cloud systems. We demonstrate the utility of our framework by tracking clouds over the ocean and land to test for systematic differences in the two physically distinct settings. ... mehrWe further evaluate our framework through case studies and statistical analyses, comparing it against two leading cloud tracking tools and two topology-based general-purpose tracking tools. The results demonstrate that incorporating system-based tracking improves the ability to capture the evolution of low-level clouds. Our framework will inform low-level cloud characterization studies that fully profit from detailed satellite data.