A Tale of Two Vortex Evolutions: Using a High-Resolution Ensemble to Assess the Impacts of Ventilation on a Tropical Cyclone Rapid Intensification Event

A Tale of Two Vortex Evolutions: Using a High-Resolution Ensemble to Assess the Impacts of Ventilation on a Tropical Cyclone Rapid Intensification Event

The multiscale nature of tropical cyclone (TC) intensity change under moderate vertical wind shear was explored through an ensemble of high-resolution simulations of Hurricane Gonzalo (2014). Ensemble intensity forecasts were characterized by large short-term (36-h) uncertainty, with a forecast inte...

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Veröffentlicht in:Monthly weather review 2023-01, Vol.151 (1), p.297-320
Hauptverfasser: Fischer, Michael S., Reasor, Paul D., Tang, Brian H., Corbosiero, Kristen L., Torn, Ryan D., Chen, Xiaomin
Format: Artikel
Sprache:eng
Schlagworte:
Advection
Air
Amplification
Columnar structure
Cyclones
Cyclonic vortexes
Deep layer
Diabatic heating
Efficiency
Ensemble forecasting
Evolution
Heat engines
High resolution
Horizontal advection
Hurricanes
Intrusion
Moist static energy
Precipitation
Resilience
Resolution
Simulation
Storms
Tropical cyclone intensities
Tropical cyclones
Troposphere
Ventilation
Vertical wind shear
Vortex breakdown
Vortex structure
Vortices
Vorticity
Wind
Wind shear
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container_start_page 297
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creator Fischer, Michael S.
Reasor, Paul D.
Tang, Brian H.
Corbosiero, Kristen L.
Torn, Ryan D.
Chen, Xiaomin
description The multiscale nature of tropical cyclone (TC) intensity change under moderate vertical wind shear was explored through an ensemble of high-resolution simulations of Hurricane Gonzalo (2014). Ensemble intensity forecasts were characterized by large short-term (36-h) uncertainty, with a forecast intensity spread of over 20 m s −1 , due to differences in the timing of rapid intensification (RI) onset. Two subsets of ensemble members were examined, referred to as early-RI and late-RI members. The two ensemble groups displayed significantly different vortex evolutions under the influence of a nearby upper-tropospheric trough and an associated dry-air intrusion. Mid-to-upper-tropospheric ventilation in late-RI members was linked to a disruption of inner-core diabatic heating, a more tilted vortex, and vortex breakdown, as the simulated TCs transitioned from a vorticity annulus toward a monopole structure. A column-integrated moist static energy (MSE) budget revealed the important role of horizontal advection in depleting MSE from the TC core, while mesoscale subsidence beneath the dry-air intrusion acted to dry a deep layer of the troposphere. Eventually, the dry-air intrusion retreated from late-RI members as vertical wind shear weakened, the magnitude of vortex tilt decreased, and late-RI members began to rapidly intensify, ultimately reaching a similar intensity as early-RI members. Conversely, the vortex structures of early-RI members were shown to exhibit greater intrinsic resilience to tilting from vertical wind shear, and early-RI members were able to fend off the dry-air intrusion relatively unscathed. The different TC intensity evolutions can be traced back to differences in the initial TC vortex structure and intensity.
doi_str_mv 10.1175/MWR-D-22-0037.1
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source American Meteorological Society; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals
subjects Advection
Air
Amplification
Columnar structure
Cyclones
Cyclonic vortexes
Deep layer
Diabatic heating
Efficiency
Ensemble forecasting
Evolution
Heat engines
High resolution
Horizontal advection
Hurricanes
Intrusion
Moist static energy
Precipitation
Resilience
Resolution
Simulation
Storms
Tropical cyclone intensities
Tropical cyclones
Troposphere
Ventilation
Vertical wind shear
Vortex breakdown
Vortex structure
Vortices
Vorticity
Wind
Wind shear
title A Tale of Two Vortex Evolutions: Using a High-Resolution Ensemble to Assess the Impacts of Ventilation on a Tropical Cyclone Rapid Intensification Event
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