Dynamic Vortex Height Evolution During Tropical Cyclone Rapid Intensification

The vertical structure of the tropical cyclone (TC) vortex can be quantified throughout the TC life cycle via the dynamic height of the vortex (DHOV) metric, which is sensitive to the rate of decay of the tangential wind field with height. Observed storms always possessed a high DHOV value prior to...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2024-12, Vol.129 (24), p.n/a
Main Authors: DesRosiers, Alexander J., Bell, Michael M.
Format: Article
Language:English
Subjects:
Control simulation
Cyclones
Cyclonic vortexes
Decay
Dynamic height
Hurricanes
Kinematics
Life cycle
Mathematical models
numerical modeling
Numerical models
rapid intensification
Simulation
Storms
tail Doppler radar
Thermal structure
tropical cyclone
Tropical cyclones
Tropopause
Troposphere
Vertical profiles
Vertical wind shear
Vortex development
Vortices
Wind
Wind shear
Winds
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Summary:The vertical structure of the tropical cyclone (TC) vortex can be quantified throughout the TC life cycle via the dynamic height of the vortex (DHOV) metric, which is sensitive to the rate of decay of the tangential wind field with height. Observed storms always possessed a high DHOV value prior to periods of rapid intensification (RI). When limited to vertically‐aligned TCs where the low‐ to mid‐level vortex tilt magnitude is small, all DHOV values are found to be large enough for RI. Vortex tilt results from environmental vertical wind shear (VWS) and a similar relationship is found in an ensemble of TCs simulated in a moderate shear environment. Once vortex tilt decreases, both the observed and ensemble TCs exhibit a concurrent increase of DHOV and intensity, indicating the metric provides useful information about changing vertical structure in both tilted and aligned TCs. The growth of DHOV during RI is closely coupled with a strengthening warm core at the upper levels. A simulation with an upper‐level jet of VWS is used to better understand the importance of the upper levels during RI by disrupting vortex development there. DHOV and intensity of the TC are effectively capped in the jet simulation relative to its counterpart in a control simulation, indicating shear can limit TC height without appreciable low‐ to mid‐level tilt. Differences in kinematic and thermal structure between the jet and control runs are found from 12‐ to 16‐km altitude, suggesting the importance of warming near the tropopause in powerful TCs. Plain Language Summary Changes in the vertical structure of the tropical cyclone (TC) wind field are important during rapid intensification (RI). Vertical wind shear (VWS), or the changes in the magnitude and direction of environmental winds with height, can tilt the TC with respect to height and cause winds averaged around the TC center to decay rapidly with height. When tilt is minimized in a TC, the winds are strong enough at higher levels to facilitate RI. During RI, the wind field continues to expand vertically and the resulting decreased decay with height depends on warming in the upper levels of the troposphere. A metric for vertical structure evaluated in observations and numerical models in this study changes in response to both the tilting of the vortex and its aligned vertical growth. Continued study of TC vertical structure is helpful in understanding how TCs grow strong and how strong they can become. Key Points Tropical cyclo
ISSN:2169-897X
2169-8996
DOI:10.1029/2024JD041710