On the Sensitivity of Tropical Cyclone Intensification under Upper-Level Trough Forcing

Leroux, Marie-Dominique; Plu, Matthieu; Roux, Frank

doi:10.1175/mwr-d-15-0224.1

Cited by 26 publications

(26 citation statements)

References 75 publications

(73 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Vollaro (1989, 1990) propose that positive EFC triggers an inward-propagating maximum in y r, which produces a balanced vortex response and thereby is associated with an inward-propagating region of vertical velocity w. This inward-propagating region of positive w would then trigger a secondary eyewall formation, associated with a temporary weakening of the TC but followed by a stronger final intensity due to the convergence of angular momentum associated with the eddies. Leroux et al (2013) found a similar evolution, with trough interaction triggering secondary eyewall formation for TC Dora in the Indian Ocean. In a follow-on study, Leroux et al (2016) found an optimal position of the TC relative to the trough in order for favorable interaction to occur.…”

Section: Introductionmentioning

confidence: 59%

On the Dynamics of Tropical Cyclone and Trough Interactions

Komaromi

Doyle

2018

Journal of the Atmospheric Sciences

View full text Add to dashboard Cite

The interaction between a tropical cyclone (TC) and an upper-level trough is simulated in an idealized framework using Coupled Ocean–Atmosphere Mesoscale Prediction System (COAMPS) for Tropical Cyclones (COAMPS-TC) on a β plane. We explore the effect of the trough on the environment, structure, and intensity of the TC. In a simulation that does not have a trough, environmental inertial stability is dominated by Coriolis, and outflow remains preferentially directed equatorward throughout the simulation. In the presence of a trough, negative storm-relative tangential wind in the base of the trough reduces the inertial stability such that the outflow shifts from equatorward to poleward. This interaction results in a ~24-h period of enhanced upper-level divergence coincident with intensification of the TC. Sensitivity tests reveal that if the TC is too far from the trough, favorable interaction does not occur. If the TC is too close to the trough, the storm weakens because of enhanced vertical wind shear. Only when the relative distance between the TC and the trough is 0.2–0.3 times the wavelength of the trough in x and 0.8–1.2 times the amplitude of the trough in y does favorable interaction and TC intensification occur. However, stochastic effects make it difficult to isolate the intensity change associated directly with the trough interaction. Outflow is found to be predominantly ageostrophic at small radii and deflects to the right (in the Northern Hemisphere) since it is unbalanced. The outflow becomes predominantly geostrophic at larger radii but not before a rightward deflection has already occurred. This finding sheds light on why the outflow accelerates toward but generally never reaches the region of lowest inertial stability.

show abstract

Section: Introductionmentioning

confidence: 59%

On the Dynamics of Tropical Cyclone and Trough Interactions

Komaromi

Doyle

2018

Journal of the Atmospheric Sciences

View full text Add to dashboard Cite

show abstract

“…How RWB affects TC development involves competing physical processes (Leroux et al 2016) and is often obscured by transient features. Studying a large number of cases is thus very demanding and likely undermined by the subjectivity in analyses.…”

Section: Variability Of Rwb Occurrence and Tc Activitymentioning

confidence: 99%

Characteristics and Impacts of Extratropical Rossby Wave Breaking during the Atlantic Hurricane Season

et al. 2017

View full text Add to dashboard Cite

This study investigates the characteristics of extratropical Rossby wave breaking (RWB) during the Atlantic hurricane season and its impacts on Atlantic tropical cyclone (TC) activity. It was found that RWB perturbs the wind and moisture fields throughout the troposphere in the vicinity of a breaking wave. When RWB occurs more frequently over the North Atlantic, the Atlantic main development region (MDR) is subject to stronger vertical wind shear and reduced tropospheric moisture; the basinwide TC counts are reduced, and TCs are generally less intense, have a shorter lifetime, and are less likely to make landfalls. A significant negative correlation was found between Atlantic TC activity and RWB occurrence during 1979-2013. The correlation is comparable to that with the MDR SST index and stronger than that with the Niño-3.4 index. Further analyses suggest that the variability of RWB occurrence in the western Atlantic is largely independent of that in the eastern Atlantic. The RWB occurrence in the western basin is more closely tied to the environmental variability of the tropical North Atlantic and is more likely to hinder TC intensification or reduce the TC lifetime because of its proximity to the central portion of TC tracks. Consequently, the basinwide TC counts and the accumulated cyclone energy have a strong correlation with western-basin RWB occurrence but only a moderate correlation with eastern-basin RWB occurrence. The results highlight the extratropical impacts on Atlantic TC activity and regional climate via RWB and provide new insights into the variability and predictability of TC activity.

show abstract

“…Intensification (i.e., positive PER) promotes the slight shrinking of TCs in all basins. Similarly, positive (Northern Hemisphere) REFC, as it promotes vortex intensification when other factors are held constant or favorable (e.g., Molinari andVollaro 1989, 1990;DeMaria et al 1993;Leroux et al 2016, and additional references therein), also promotes a reduction in storm sizes. Positive Z850 (Northern Hemisphere) appears to be related to TC growth in the SHEM and WPAC where TCs often form in monsoon trough environments (equatorial westerlies converging with poleward easterlies).…”

Section: A Selected Variables and Interpretationmentioning

confidence: 99%

A Global Statistical–Dynamical Tropical Cyclone Wind Radii Forecast Scheme

Knaff

Sampson

Chirokova

2017

Weather and Forecasting

View full text Add to dashboard Cite

Forecasts of tropical cyclone (TC) surface wind structure have recently begun to show some skill, but the number of reliable forecast tools, mostly regional hurricane and select global models, remains limited. To provide additional wind structure guidance, this work presents the development of a statistical–dynamical method to predict tropical cyclone wind structure in terms of wind radii, which are defined as the maximum extent of the 34-, 50-, and 64-kt (1 kt = 0.514 m s−1) winds in geographical quadrants about the center of the storm. The basis for TC size variations is developed from an infrared satellite-based record of TC size, which is homogenously calculated from a global sample. The change in TC size is predicted using a statistical–dynamical approach where predictors are based on environmental diagnostics derived from global model forecasts and observed storm conditions. Once the TC size has been predicted, the forecast intensity and track are used along with a parametric wind model to estimate the resulting wind radii. To provide additional guidance for applications and users that require forecasts of central pressure, a wind–pressure relationship that is a function of TC motion, intensity, wind radii (i.e., size), and latitude is then applied to these forecasts. This forecast method compares well with similar wind structure forecasts made by global forecast and regional hurricane models and when these forecasts are used as a member of a simple consensus; its inclusion improves the forecast performance of the consensus.

show abstract

On the Sensitivity of Tropical Cyclone Intensification under Upper-Level Trough Forcing

Cited by 26 publications

References 75 publications

On the Dynamics of Tropical Cyclone and Trough Interactions

On the Dynamics of Tropical Cyclone and Trough Interactions

Characteristics and Impacts of Extratropical Rossby Wave Breaking during the Atlantic Hurricane Season

A Global Statistical–Dynamical Tropical Cyclone Wind Radii Forecast Scheme

Contact Info

Product

Resources

About