Are Eyewall Replacement Cycles Governed Largely by Axisymmetric Balance Dynamics?

Abarca, Sergio F.; Montgomery, Michael T.

doi:10.1175/jas-d-14-0151.1

Cited by 24 publications

(11 citation statements)

References 13 publications

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“…Such waves are difficult to see in observations; Corbosiero et al (2006) used radar reflectivity over several hours with 5-min temporal and 750-m spatial resolution over 150 km of radius to identify these features. A numerical simulation by Abarca and Corbosiero (2011) made similar arguments on the role of Rossby waves on ERCs. In principle, this process could create a secondary eyewall because the increase in cyclonic flow from the momentum accumulation can enhance surface fluxes, convection, and cyclonic vorticity.…”

Section: Introductionmentioning

confidence: 65%

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Repeated Eyewall Replacement Cycles in Hurricane Frances (2004)

Molinari

Zhang

Rogers

et al. 2019

Monthly Weather Review

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Hurricane Frances (2004) represented an unusual event that produced three consecutive overlapping eyewall replacement cycles (ERCs). Their evolution followed some aspects of the typical ERC. The strong primary eyewalls contracted and outward-sloping secondary eyewalls formed near 3 times the radius of maximum winds. Over time these secondary eyewalls shifted inward, became more upright, and replaced the primary eyewalls. In other aspects, however, the ERCs in Hurricane Frances differed from previously described composites. The outer eyewall wind maxima became stronger than the inner in only 12 h, versus 25 h for average ERCs. More than 15 m s−1 outflow peaked in the upper troposphere during each ERC. Relative vorticity maxima peaked at the surface but extended to mid- and upper levels. Mean 200-hPa zonal velocity was often from the east, whereas ERC environments typically have zonal flow from the west. These easterlies were produced by an intense upper anticyclone slightly displaced from the center and present throughout the period of multiple ERCs. Inertial stability was low at almost all azimuths at 175 hPa near the 500-km radius during the period of interest. It is hypothesized that the reduced resistance to outflow associated with low inertial stability aloft induced deep upward motion and rapid intensification of the secondary eyewalls. The annular hurricane index of Knaff et al. showed that Hurricane Frances met all the criteria for annular hurricanes, which make up only 4% of all storms. It is argued that the annular hurricane directly resulted from the repeated ERCs following Wang’s reasoning.

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Section: Introductionmentioning

confidence: 65%

“…Considerable controversy exists as to whether the boundary layer processes in the outer eyewall are balanced or unbalanced (Rozoff et al 2012;Huang et al 2012;Kepert 2013;Montgomery 2014, Abarca andMontgomery 2015;Wu et al 2016), but there is little doubt that the resulting contracting outer eyewall is based in the boundary layer.…”

Section: Introductionmentioning

confidence: 99%

Repeated Eyewall Replacement Cycles in Hurricane Frances (2004)

Molinari

Zhang

Rogers

et al. 2019

Monthly Weather Review

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“…Detecting and tracking the rotational center of tropical cyclones (TC) are critical for objective TC-intensity estimation [1,2], the detection of rapid intensification [3], dynamic diagnosis [4][5][6] and TC climatological descriptions [7][8][9][10][11]. Studies have shown that the overall conclusions could be heavily sensitive to the accuracy of the center [12,13], because positioning the center is the initial step in most of the applications.…”

Section: Introductionmentioning

confidence: 99%

Objective Center-Finding Algorithm for Tropical Cyclones in Numerical Models

et al. 2019

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Precise center-detection of tropical cyclones (TCs) is critical for dynamic analysis in high resolution model data. The existence of both smaller scale perturbations and larger scale circulations could reduce the accuracy of center positioning. In this study, an objective center-finding algorithm is developed based on a two-dimensional Fourier filter and a vorticity centroid algorithm. This proposed algorithm is able to automatically adjust its parameters according to the scale of the target vortex instead of using artificially prescribed parameters in previous research. What’s more, this new algorithm has been optimized and validated by a hundred idealized vortexes with different sizes and small-scale perturbations. A high-resolution simulation of Typhoon Soudelor (2015) was used to evaluate the performance of the new algorithm, and the proposed objective center-finding algorithm was found able to detect a precise and reliable center.

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“…Strong TCs often have been observed with an inner (primary) and outer (secondary) eyewall separated by a region of minimal convection (Willoughby et al 1982). Although variable and not always completed, the ERC typically begins with the formation of the outer eyewall, continues as convection intensifies in the outer eyewall and weakens in the inner eyewall, and concludes as the inner eyewall fully decays and the outer eyewall contracts toward the storm center (Rozoff et al 2008;Sitkowski et al 2011;Kossin and Sitkowski 2012;Abarca and Montgomery 2013). Important intensity changes occur concurrently with these changes in convective structure, so much so that Sitkowski et al (2011) classified ERCs into three intensity-based phases: intensification, weakening, and reintensification.…”

Section: Introductionmentioning

confidence: 99%

“…One of the objectives of the current study is to present a geostationary satellitebased technique that highlights the structural evolution of deep convection during the ERC of Typhoon Sinlaku (2008). Given the role of boundary layer dynamics in ERCs [e.g., the boundary layer spinup mechanisms proposed by Abarca andMontgomery (2014, 2015)], another objective is to compare the evolution of deep convection with the concurrent evolution of the surface and flight-level wind measurements within and above the boundary layer, respectively. The surface winds were measured by the Stepped-Frequency Microwave Radiometer (SFMR), and the flight-level winds were computed by the aircraft data system, both on board the WC-130J.…”

Section: Introductionmentioning

confidence: 99%

Satellite and Aircraft Observations of the Eyewall Replacement Cycle in Typhoon Sinlaku (2008)

Sanabia

Barrett

Celone

et al. 2015

Monthly Weather Review

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Satellite and aircraft observations of the concurrent evolution of cloud-top brightness temperatures (BTs) and the surface and flight-level wind fields were examined before and during an eyewall replacement cycle (ERC) in Typhoon Sinlaku (2008) as part of The Observing System Research and Predictability Experiment (THORPEX) Pacific Asian Regional Campaign (T-PARC) and the Tropical Cyclone Structure 2008 (TCS08) field campaign. The structural evolution of deep convection through the life cycle of the ERC was clearly evident in the radial variation of positive water vapor (WV) minus infrared (IR) brightness temperature differences over the 96-h period. Within this framework, the ERC was divided into six broadly defined stages, wherein convective processes (including eyewall development and decay) were analyzed and then validated using microwave data. Dual maxima in aircraft wind speeds and geostationary satellite BTs along flight transects through Sinlaku were used to document the temporal evolution of the ERC within the TC inner core. Negative correlations were found between IR BTs and surface wind speeds, indicating that colder cloud tops were associated with stronger surface winds. Spatial lags indicated that the strongest surface winds were located radially inward of both the flight-level winds and coldest cloud tops. Finally, timing of the ERC was observed equally in IR and WV minus IR (WVIR) BTs with one exception. Decay of the inner eyewall was detected earlier in the WVIR data. These findings highlight the potential utility of WVIR and IR BT radial profiles, particularly so for basins without active aircraft weather reconnaissance programs such as the western North Pacific.

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Are Eyewall Replacement Cycles Governed Largely by Axisymmetric Balance Dynamics?

Cited by 24 publications

References 13 publications

Repeated Eyewall Replacement Cycles in Hurricane Frances (2004)

Repeated Eyewall Replacement Cycles in Hurricane Frances (2004)

Objective Center-Finding Algorithm for Tropical Cyclones in Numerical Models

Satellite and Aircraft Observations of the Eyewall Replacement Cycle in Typhoon Sinlaku (2008)

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