Large-scale patterns of small-scale vorticity interactions foster moist convection during cyclogenesis

TL;DR

This study reveals how small-scale vorticity interactions organize into large-scale patterns that foster moist convection during cyclone formation, highlighting the importance of local coherence in predicting cyclogenesis.

Contribution

It introduces a novel network-based approach to analyze the role of small-scale vorticity interactions in cyclone development, linking local coherence to large-scale organization.

Findings

Small-scale vorticity interactions form large-scale emergent patterns.

Organized moist convection correlates with coherent vorticity regions during cyclone intensification.

Large-scale modes of coherence propagation are key to cyclone formation.

Abstract

The formation and intensification of a tropical cyclone is a complex phenomenon involving several feedback interactions between momentum and energetics of the storm, and across multiple spatio-temporal scales. Background vorticity interactions in the turbulent atmosphere play a crucial role in the formation of cyclones. How these vorticity interactions lead to convective organization and sustain a disastrous cyclonic vortex amidst a turbulent atmosphere remains elusive. Moreover, what processes distinguish depressions that develop into a cyclone from those that do not? Here, we investigate the role of small-scale vorticity interactions in the background flow in sustaining large-scale organization during the emergence of a cyclone. We construct time-varying complex networks where geographical locations are nodes and connections between nodes represent short-time vorticity correlations. Only those nodes are connected that are in spatial proximity corresponding to sub-meso length scales. Each network is constructed for 29 hours of data; consecutive networks are separated by three hours, thus revealing the evolution of local coherence in vorticity dynamics. We discover that small-scale vorticity interactions manifest as large-scale emergent patterns. Further, we establish that organized moist convection is significantly correlated to regions of locally coherent vorticity dynamics during the intensification of a depression that forms a cyclone; however, such correlations are not sustained during non-developing cases. Using modal analysis of time-evolving network connectivity, we show that these large-scale patterns are essentially large-scale modes of propagation of coherence in small-scale vorticity dynamics. We explain that such propagation is facilitated by moisture feedback at small-scales and self-organized patterns at large-scales.