# Characterizing the energetics of multi-scale asymmetries during tropical   cyclone rapid intensity changes

**Authors:** Saiprasanth Bhalachandran, D. R. Chavas, F. D. Marks Jr., S. Dubey, A., Shreevastava, and T. N. Krishnamurti

arXiv: 1908.03618 · 2020-02-19

## TL;DR

This study introduces a novel energetics-based method to analyze multi-scale asymmetries in tropical cyclones during rapid intensity changes, revealing scale-dependent mechanisms and potential early-warning indicators.

## Contribution

It presents a new approach to quantify and compare the energetics of asymmetries at multiple scales, improving understanding beyond mean-eddy partitioning.

## Key findings

- Baroclinic conversion drives asymmetry growth/decay at individual scales.
- Kinetic energy transactions occur between different asymmetry scales.
- Asymmetry energetics are largely independent of the mean flow.

## Abstract

Our collective understanding of azimuthally-asymmetric features within the coherent structure of a tropical cyclone (TC) continues to improve with the availability of more detailed observations and high-resolution model outputs. However, a precise understanding of how these asymmetries impact TC intensity changes is lacking. Prior attempts at investigating the asymmetric impacts follow a mean-eddy partitioning that condenses the effect of all the asymmetries into one term and fails to highlight the differences in the role of asymmetries at different scales. In this study, we present a novel energetics-based approach to analyze the asymmetric impacts at multiple length-scales during periods of TC rapid intensity changes. Using model outputs of TCs under low and high shear, we compute the different energy pathways that enhance/suppress the growth of multi-scale asymmetries in the wavenumber (WN) domain. We then compare and contrast the energetics of the mean flow field (WN 0) with that of the persistent, coherent vortex-scale asymmetric structures (WNs 1,2) and the more local, transient, sub-vortex-scale asymmetries (WNs $\geq$ 3). We find in our case-studies that the dominant mechanisms of growth/decay of the asymmetries are the baroclinic conversion from available potential to kinetic energy at individual scales of asymmetries, and the transactions of kinetic energy between the asymmetries of various length-scales; rather than the barotropic mean-eddy transactions as is typically assumed. Our case-study analysis further shows that the growth/decay of asymmetries is largely independent of the mean. Certain aspects of eddy energetics can potentially serve as early-warning indicators of TC rapid intensity changes.

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/1908.03618/full.md

## References

79 references — full list in the complete paper: https://tomesphere.com/paper/1908.03618/full.md

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Source: https://tomesphere.com/paper/1908.03618