The Impact of Outer-Core Surface Heat Fluxes on the Convective Activities and Rapid Intensification of Tropical Cyclones

Abstract The rapid intensification (RI) of Typhoon Soudelor (2015) is simulated using a full-physics model. To investigate how the outer-core surface heat fluxes affect tropical cyclone (TC) structure and RI processes, a series of numerical experiments are performed by suppressing surface heat fluxe...

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Bibliographic Details
Published inJournal of the atmospheric sciences Vol. 77; no. 11; pp. 3907 - 3927
Main Authors Peng, Chin-Hsuan, Wu, Chun-Chieh
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 01.11.2020
Subjects
Aggregation
Amplification
Convection
Correlation
Correlation analysis
Cyclones
Heat flux
Heat transfer
Hurricanes
Numerical experiments
Physics
Potential vorticity
Stability
Surface wind
Tropical climate
Tropical cyclones
Typhoons
Updraft
Vorticity
Winds
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Summary:Abstract The rapid intensification (RI) of Typhoon Soudelor (2015) is simulated using a full-physics model. To investigate how the outer-core surface heat fluxes affect tropical cyclone (TC) structure and RI processes, a series of numerical experiments are performed by suppressing surface heat fluxes between various radii. It is found that a TC would become quite weaker when the surface heat fluxes are suppressed outside the radius of 60 or 90 km [the radius of maximum surface wind in the control experiment (CTRL) at the onset of RI is roughly 60 km]. However, interestingly, the TC would experience stronger RI when the surface heat fluxes are suppressed outside the radius of 150 km. For those sensitivity experiments with capped surface heat fluxes, the members with greater intensification rate show stronger inner-core mid- to upper-level updrafts and higher heating efficiency prior to the RI periods. Although the outer-core surface heat fluxes in these members are suppressed, the inner-core winds become stronger, extracting more ocean energy from the inner core. Greater outer-core low-level stability in these members results in aggregation of deep convection and subsequent generation and concentration of potential vorticity inside the inner core, thus confining the strongest winds therein. The abovementioned findings are also supported by partial-correlation analyses, which reveal the positive correlation between the inner-core convection and subsequent 6-h intensity change, and the competition between the inner-core and outer-core convections (i.e., eyewall and outer rainbands).
ISSN:0022-4928
1520-0469
DOI:10.1175/JAS-D-19-0348.1