Tropopause Evolution in a Rapidly Intensifying Tropical Cyclone: A Static Stability Budget Analysis in an Idealized Axisymmetric Framework

Upper-level static stability (N2) variations can influence the evolution of the transverse circulation and potential vorticity in intensifying tropical cyclones (TCs). This paper examines these variations during the rapid intensification (RI) of a simulated TC. Over the eye, N2 near the tropopause d...

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Bibliographic Details
Published in:Journal of the atmospheric sciences 2019-01, Vol.76 (1), p.209-229
Main Authors: Duran, Patrick, Molinari, John
Format: Article
Language:English
Subjects:
Advection
Budgets
Clouds
Cooling
Cyclones
Destabilization
Differential thermal analysis
Diurnal
Diurnal cycle
Diurnal variations
Evolution
Gravitational waves
Hurricanes
Inflow
Lower stratosphere
Outflow
Plant cover
Potential temperature
Potential vorticity
Radiation
Radiative cooling
Simulation
Stability analysis
Static stability
Storms
Stratosphere
Tropical climate
Tropical cyclones
Tropopause
Troposphere
Turbulence
Upper troposphere
Vertical circulation
Vertical stability
Vertical wind shear
Vorticity
Wind shear
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Summary:Upper-level static stability (N2) variations can influence the evolution of the transverse circulation and potential vorticity in intensifying tropical cyclones (TCs). This paper examines these variations during the rapid intensification (RI) of a simulated TC. Over the eye, N2 near the tropopause decreases and the cold-point tropopause rises by up to 4 km at the storm center. Outside of the eye, N2 increases considerably just above the cold-point tropopause and the tropopause remains near its initial level. A budget analysis reveals that the advection terms, which include differential advection of potential temperature θ and direct advection of N2, are important throughout the upper troposphere and lower stratosphere. These terms are particularly pronounced within the eye, where they destabilize the layer near and above the cold-point tropopause. Outside of the eye, a radial–vertical circulation develops during RI, with strong outflow below the tropopause and weak inflow above. Differential advection of θ near the outflow jet provides forcing for stabilization below the outflow maximum and destabilization above. Turbulence induced by vertical wind shear on the flanks of the outflow maximum also modifies the vertical stability profile. Meanwhile, radiative cooling tendencies at the top of the cirrus canopy generally act to destabilize the upper troposphere and stabilize the lower stratosphere. The results suggest that turbulence and radiation, alongside differential advection, play fundamental roles in the upper-level N2 evolution of TCs. These N2 tendencies could have implications for both the TC diurnal cycle and the tropopause-layer potential vorticity evolution in TCs.
ISSN:0022-4928
1520-0469
DOI:10.1175/JAS-D-18-0097.1