Environmental influences on the intensity changes of tropical cyclones over the western North Pacific

Shu, Shoujuan; Zhang, Fuqing; Ming, Jie; Wang, Yuan

doi:10.5194/acp-14-6329-2014

Cited by 27 publications

(23 citation statements)

References 63 publications

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“…The greater tilting of the horizontal vorticity was a result of the correlation between upward motion and the horizontal vorticity due to the upper-tropospheric trough. From this perspective, the outcome of a TC-trough interaction depends not only on the size and strength of the PV associated with the trough, as stated by Hanley et al (2001), but also on the interaction between convection and the trough-induced shear as suggested by Shu et al (2014). This conclusion was also supported by sensitivity experiments in which AHW forecasts with perturbed initial conditions had greater MSLP changes in response to variability of the downshear convection than in response to variability of the upper-tropospheric trough.…”

Section: Discussionmentioning

confidence: 97%

“…Oftentimes a moderately sheared environment stems from an upper-tropospheric trough in close proximity to a TC (e.g., Hanley et al 2001; Davis and Bosart 2002;Molinari et al 2006;Shu et al 2014). In a composite study of TC-trough interactions in the North Atlantic, Hanley et al (2001) found that TCs are more likely to intensify than weaken after interacting with uppertropospheric troughs.…”

Section: B Literature Reviewmentioning

confidence: 96%

“…Hanley et al (2001) explained that TC intensification was favored in situations of smaller and weaker upper-tropospheric potential vorticity (PV) disturbances than in the cases of TC weakening due to the weaker shear and stronger divergence aloft. However, the composite study of western North Pacific TCs of Shu et al (2014) showed that uppertropospheric troughs can inhibit intensification by promoting dry-air intrusion and reducing convective activity. Although Shu et al (2014) restricted their study to TCs near the western North Pacific subtropical high, their results suggest that upper-tropospheric troughs could provide a mechanism for dry-air entrainment, which is a known detrimental effect of vertical wind shear (Riemer et al 2010;Munsell et al 2013;Tang and Emanuel 2012).…”

Section: B Literature Reviewmentioning

confidence: 96%

“…However, the composite study of western North Pacific TCs of Shu et al (2014) showed that uppertropospheric troughs can inhibit intensification by promoting dry-air intrusion and reducing convective activity. Although Shu et al (2014) restricted their study to TCs near the western North Pacific subtropical high, their results suggest that upper-tropospheric troughs could provide a mechanism for dry-air entrainment, which is a known detrimental effect of vertical wind shear (Riemer et al 2010;Munsell et al 2013;Tang and Emanuel 2012). These contradicting results warrant further investigation to discern the role of uppertropospheric troughs on TC intensity changes.…”

Section: B Literature Reviewmentioning

confidence: 96%

See 3 more Smart Citations

An Ensemble Approach to Investigate Tropical Cyclone Intensification in Sheared Environments. Part II: Ophelia (2011)

Ríos-Berríos

Torn

Davis

2016

Journal of the Atmospheric Sciences

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The mechanisms leading to tropical cyclone (TC) intensification amid moderate vertical wind shear can vary from case to case, depending on the vortex structure and the large-scale conditions. To search for similarities between cases, this second part investigates the rapid intensification of Hurricane Ophelia (2011) in an environment characterized by 200-850-hPa westerly shear exceeding 8 m s 21 . Similar to Part I, a 96-member ensemble was employed to compare a subset of members that predicted Ophelia would intensify with another subset that predicted Ophelia would weaken. This comparison revealed that the intensification of Ophelia was aided by enhanced convection and midtropospheric moisture in the downshear and left-of-shear quadrants. Enhanced left-of-shear convection was key to the establishment of an anticyclonic divergent outflow that forced a nearby upper-tropospheric trough to wrap around Ophelia. A vorticity budget showed that deep convection also contributed to the enhancement of vorticity within the inner core of Ophelia via vortex stretching and tilting of horizontal vorticity enhanced by the upper-tropospheric trough. These results suggest that TC intensity changes in sheared environments and in the presence of upper-tropospheric troughs highly depend on the interaction between convective-scale processes and the large-scale flow. Given the similarities between Part I and this part, the results suggest that observations from the three-dimensional moisture and wind fields could improve both forecasting and understanding of TC intensification in moderately sheared environments.

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Section: Discussionmentioning

confidence: 97%

Section: B Literature Reviewmentioning

confidence: 96%

Section: B Literature Reviewmentioning

confidence: 96%

Section: B Literature Reviewmentioning

confidence: 96%

See 2 more Smart Citations

An Ensemble Approach to Investigate Tropical Cyclone Intensification in Sheared Environments. Part II: Ophelia (2011)

Ríos-Berríos

Torn

Davis

2016

Journal of the Atmospheric Sciences

View full text Add to dashboard Cite

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“…Apart from looking at the magnitude of VWS, the direction of VWS has also found to be important for TC genesis and intensity. Some studies show that easterly shear is more favorable to TC intensification than westerly shear (Ritchie and Frank 2007, Zeng et al 2010, Shu et al 2014. The beta-induced northwesterly shear within the inner core of the TC could partly offset the easterly shear and thereby results in weaker VWS and favors TC intensification.…”

Section: Introductionmentioning

confidence: 99%

Does strong vertical wind shear certainly lead to the weakening of a tropical cyclone?

Chan

Wang

et al. 2019

Environ. Res. Commun.

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This is a preliminary pilot study giving an important insight into the feasible improvement of existing prediction of tropical cyclone (TC) intensity change by revisiting the relevant impact of vertical wind shear (VWS), where VWS is commonly defined as the environmental horizontal wind difference between the top and bottom of the shear layer. Macroscopically, strong VWS has been concluded to be detrimental to TC intensification. However, this study, from the microscopic point of view, shows that given the same thermal forcing, strong VWS does not certainly lead to TC weakening. Considering the magnitude, direction or orientation of VWS alone is no longer comprehensively physical enough for predicting the change in TC intensity. Instead, the whole profile of VWS (VWSP), that is the environmental horizontal winds at all levels within the shear layer, determines. The ventilation of dry and low-entropy air that are directly or indirectly driven by the environmental flows in the upper-, mid-and lower-troposphere could modify TC intensity in various extent. The VWSP is proposed to be a new potential proxy or update of the current TC intensity change prediction. Tropical cyclone recurvature: an intrinsic property? Geophys. Res. Lett. 43 8769-74 Cram T A, Persing J, Montgomery M T and Braun S A 2007 A lagrangian trajectory view on transport and mixing processes between the eye, eyewall, and environment using a high-resolution simulation of Hurricane Bonnie (1998) J. Atmos. Sci. 64 1835-56 DeMaria M 1996 The effect of vertical shear on tropical cyclone intensity change J. Atmos. Sci. 53 2076-88 DeMaria M 2009 A simplified dynamical system for tropical cyclone intensity prediction Mon. Weather Rev. 137 68-82 DeMaria M and Kaplan J 1999 An updated statistical hurricane intensity prediction scheme (SHIPS) for the Atlantic and eastern North Pacific basins Weather and Forecasting 14 326-37 DeMaria M, Mainelli M, Shay L K, Knaff J A and Kaplan J 2005 Further improvements to the statistical hurricane intensity prediction scheme (SHIPS) Weather and Forecasting 20 531-43 Donelan M A et al 2004 On the limiting aerodynamic roughness of the ocean in very strong winds Geophys. Res. Lett. 31 L18306 Emanuel K A 1989 The finite-amplitude nature of tropical cyclogenesis J. Atmos. Sci. 46 3431-56 Emanuel K A, DesAutels C, Holloway C and Korty R 2004 Environmental control of tropical cyclone intensity J. Atmos. Sci. 61 843-58 Finocchio P M and Majumdar S J 2017 A statistical perspective on wind profiles and vertical wind shear in tropical cyclone environments of the Northern Hemisphere Mon. Weather Rev. 145 361-78 Finocchio P M, Majumdar S J, Nolan D S and Iskandarani M 2016 Idealized tropical cyclone responses to the height and depth of environment vertical wind shear Mon. Weather Rev. 129 2155-75 Frank W M and Ritchie E A 2001 Effects of vertical wind shear on the intensity and structure of numerically simulated hurricanes Mon. Weather Rev. 129 2249-69 Ge X, Li T and Peng M 2013 Effects of vertical shears and midlevel dry air on tropical...

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Understanding of the Effect of Climate Change on Tropical Cyclone Intensity: A Review

Zhao

Wang

et al. 2022

Adv. Atmos. Sci.

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The effect of climate change on tropical cyclone intensity has been an important scientific issue for a few decades. Although theory and modeling suggest the intensification of tropical cyclones in a warming climate, there are uncertainties in the assessed and projected responses of tropical cyclone intensity to climate change. While a few comprehensive reviews have already provided an assessment of the effect of climate change on tropical cyclone activity including tropical cyclone intensity, this review focuses mainly on the understanding of the effect of climate change on basin-wide tropical cyclone intensity, including indices for basin-wide tropical cyclone intensity, historical datasets used for intensity trend detection, environmental control of tropical cyclone intensity, detection and simulation of tropical cyclone intensity change, and some issues on the assessment of the effect of climate change on tropical cyclone intensity. In addition to the uncertainty in the historical datasets, intertwined natural variabilities, the considerable model bias in the projected large-scale environment, and poorly simulated inner-core structures of tropical cyclones, it is suggested that factors controlling the basin-wide intensity can be different from individual tropical cyclones since the assessment of the effect of climate change treats tropical cyclones in a basin as a whole.

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Environmental influences on the intensity changes of tropical cyclones over the western North Pacific

Cited by 27 publications

References 63 publications

An Ensemble Approach to Investigate Tropical Cyclone Intensification in Sheared Environments. Part II: Ophelia (2011)

An Ensemble Approach to Investigate Tropical Cyclone Intensification in Sheared Environments. Part II: Ophelia (2011)

Does strong vertical wind shear certainly lead to the weakening of a tropical cyclone?

Understanding of the Effect of Climate Change on Tropical Cyclone Intensity: A Review

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