Reexamining the Near-Core Radial Structure of the Tropical Cyclone Primary Circulation: Implications for Vortex Resiliency

Mallen, Kevin J.; Montgomery, Michael T.; Wang, Bin

doi:10.1175/jas-3377.1

Cited by 164 publications

(171 citation statements)

References 58 publications

Supporting

Mentioning

142

Contrasting

Order By: Relevance

“…Therefore, if ∂ V /∂ R is not known from observations, then a guess can be made for the decay rate n, and the relation ∂ V /∂ R = −n(V /R) can be used once V and R are specified. Typical values for n for tropical cyclones of various intensity were determined by Mallen et al (2005, their Table 2). We also note that the largest absolute value of ∂ V /∂ R for Fig.…”

Section: Resultsmentioning

confidence: 99%

A Simple Method for Simulating Wind Profiles in the Boundary Layer of Tropical Cyclones

Bryan

Worsnop

Lundquist

et al. 2016

Boundary-Layer Meteorol

View full text Add to dashboard Cite

A method to simulate characteristics of wind speed in the boundary layer of tropical cyclones in an idealized manner is developed and evaluated. The method can be used in a single-column modelling set-up with a planetary boundary-layer parametrization, or within large-eddy simulations (LES). The key step is to include terms in the horizontal velocity equations representing advection and centrifugal acceleration in tropical cyclones that occurs on scales larger than the domain size. Compared to other recently developed methods, which require two input parameters (a reference wind speed, and radius from the centre of a tropical cyclone) this new method also requires a third input parameter: the radial gradient of reference wind speed. With the new method, simulated wind profiles are similar to composite profiles from dropsonde observations; in contrast, a classic Ekman-type method tends to overpredict inflow-layer depth and magnitude, and two recently developed methods for tropical cyclone environments tend to overpredict near-surface wind speed. When used in LES, the new technique produces vertical profiles of total turbulent stress and estimated eddy viscosity that are similar to values determined from low-level aircraft flights in tropical cyclones. Temporal spectra from LES produce an inertial subrange for frequencies 0.1 Hz, but only when the horizontal grid spacing 20 m.

show abstract

Section: Resultsmentioning

confidence: 99%

A Simple Method for Simulating Wind Profiles in the Boundary Layer of Tropical Cyclones

Bryan

Worsnop

Lundquist

et al. 2016

Boundary-Layer Meteorol

View full text Add to dashboard Cite

show abstract

“…Historical data does not provide information of a storm's dimension and therefore it is difficult to use historical datasets in order to determine their PI. Further studies shed light on the radial wind contours [17] and characterization of storm's dimension [18] and the drag coefficient [19]. With this background and further simplifications, the Power Dissipation Index (PDI) of a TC is given by [3]:…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Towards Dependence of Tropical Cyclone Intensity on Sea Surface Temperature and Its Response in a Warming World

Arora

Dash

2016

Climate

View full text Add to dashboard Cite

Tropical Cyclone (TC) systems affect global ocean heat transport due to mixing of the upper ocean and impact climate dynamics. A higher Sea Surface Temperature (SST), other influencing factors remaining supportive, fuels TC genesis and intensification. The atmospheric thermodynamic profile, especially the sea-air temperature contrast (SAT), also contributes due to heat transfer and affects TC's maximum surface wind speed (V max ) explained by enthalpy exchange processes. Studies have shown that SST can approximately be used as a proxy for SAT. As a part of an ongoing effort in this work, we simplistically explored the connection between SST and V max from a climatological perspective. Subsequently, estimated V max is applied to compute Power Dissipation Index (an upper limit on TC's destructive potential). The model is developed using long-term observational SST reconstructions employed on three independent SST datasets and validated against an established model. This simple approach excluded physical parameters, such as mixing ratio and atmospheric profile, however, renders it generally suitable to compute potential intensity associated with TCs spatially and weakly temporally and performs well for stronger storms. A futuristic prediction by the HadCM3 climate model under doubled CO 2 indicates stronger storm surface wind speeds and rising SST, especially in the Northern Hemisphere.

show abstract

“…The vertical structure of the initial vortex is in the radiative-convective-equilibrium state (Nolan, 2011;Nolan et al, 2013). Rather than using the fairly narrow tangential wind profile generated by a Gaussian vorticity distribution, our simulations use a modified Rankine vortex with decay parameter as 0.4, which is more realistic for the development stage (Mallen et al, 2005). The SST is fixed to 28 • C. The domain-wide wind profile is purely zonal, with U(p) = −5 ms −1 from the surface to 850 hPa, increasing with the shape of a cosine as a function of log-pressure height to 5 ms −1 at 200 hPa, then remaining at this value for all greater heights.…”

Section: The Numerical Model and Experimental Designmentioning

confidence: 99%

Effects of Landfall Location and Approach Angle of an Idealized Tropical Cyclone over a Long Mountain Range

2016

View full text Add to dashboard Cite

Effects of landfall location and approach angle on track deflection associated with a tropical cyclone (TC) passing over an idealized and Central Appalachian Mountain is investigated by a series of idealized numerical experiments. When the TC landfalls on the central portion of the mountain range, it is deflected to the south upstream, passes over the mountain anticyclonically, and then moves westward downstream. The TC motion is steered by the positive vorticity tendency (VT) which is dominated by horizontal vorticity advection upstream and downstream, but with additional influence from the stretching and residual terms, which are mainly associated with diabatic heating and frictional effects. The track deflection mechanism upstream and downstream is similar to the dry flow in previous study, but is very different in the vicinity of the mountain. When the TC landfalls near the northern (southern) tip, it experiences less (more) southward deflection due to stronger (weaker) vorticity advection around the tip. When the TC approaches the mountain range from the southeast and landfalls on the northern tip, center, or southern tip, the track deflections are similar to those embedded in an easterly flow but with weaker orographic blocking. These results are similar to the cases simulated in the dry flow in previous study, except that there is no track discontinuity due to the weaker orographic blocking associated with strong TC convection. When a TC moves along the north-south mountain range from the south, it tends to deflect toward the mountain and then crosses over to the other side at later time. In these cases, the positive VT is influenced by all horizontal vorticity advection, vorticity stretching (diabatic heating), and residual (friction) terms due to longer and stronger interaction with the mountain range. The vorticity stretching is mainly caused by diabatic heating in the moist flow, instead of by lee slope vorticity stretching in the previous study for dry flow.

show abstract

Reexamining the Near-Core Radial Structure of the Tropical Cyclone Primary Circulation: Implications for Vortex Resiliency

Cited by 164 publications

References 58 publications

A Simple Method for Simulating Wind Profiles in the Boundary Layer of Tropical Cyclones

A Simple Method for Simulating Wind Profiles in the Boundary Layer of Tropical Cyclones

Towards Dependence of Tropical Cyclone Intensity on Sea Surface Temperature and Its Response in a Warming World

Effects of Landfall Location and Approach Angle of an Idealized Tropical Cyclone over a Long Mountain Range

Contact Info

Product

Resources

About