A Global Climatology of Baroclinically Influenced Tropical Cyclogenesis

McTaggart‐Cowan, Ron; Galarneau, Thomas J.; Bosart, Lance F.; Moore, Richard W.; Martius, Olivia

doi:10.1175/mwr-d-12-00186.1

Cited by 78 publications

(63 citation statements)

References 106 publications

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“…Finally, if a storm does not move at least 10 degrees in latitude over its whole life cycle, no transition is recorded even if one 'appears' in the CPS CA because this is not reconcilable with understandings of ET as the process of storms of tropical genesis moving into the midlatitudes. By implementing these constraints results were considerably improved, for example removing the higher latitude baroclinically induced TCs (McTaggart-Cowan et al, 2013) and monsoonal storms in the northern Indian Ocean that superficially resemble ET in the CPS.…”

Section: Determination Of Etmentioning

confidence: 99%

Objective determination of the extratropical transition of tropical cyclones in the Northern Hemisphere

Studholme¹,

Hodges

Brierley

2015

Tellus A: Dynamic Meteorology and Oceanography

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A B S T R A C T Extratropical transition (ET) has eluded objective identification since the realisation of its existence in the 1970s. Recent advances in numerical, computational models have provided data of higher resolution than previously available. In conjunction with this, an objective characterisation of the structure of a storm has now become widely accepted in the literature. Here we present a method of combining these two advances to provide an objective method for defining ET. The approach involves applying K-means clustering to isolate different life-cycle stages of cyclones and then analysing the progression through these stages. This methodology is then tested by applying it to five recent years from the European Centre of Medium-Range Weather Forecasting operational analyses. It is found that this method is able to determine the general characteristics for ET in the Northern Hemisphere. Between 2008 and 2012, 54% (97, 32 of 59) of Northern Hemisphere tropical storms are estimated to undergo ET. There is great variability across basins and time of year. To fully capture all the instances of ET is necessary to introduce and characterise multiple pathways through transition. Only one of the three transition types needed has been previously well-studied. A brief description of the alternate types of transitions is given, along with illustrative storms, to assist with further study.

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Section: Determination Of Etmentioning

confidence: 99%

Objective determination of the extratropical transition of tropical cyclones in the Northern Hemisphere

Studholme¹,

Hodges

Brierley

2015

Tellus A: Dynamic Meteorology and Oceanography

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“…Besides the possible impacts of the NAO, extratropical frontal systems may affect Atlantic TC activity by contributing to TC formation, which is known as the tropical transition Bosart 2003, 2004;McTaggart-Cowan et al 2013). Notably, the tropical transition is often accompanied by potential vorticity (PV) streamers associated with anticyclonic Rossby wave breaking (RWB) (Davis and Bosart 2004;Galarneau et al 2015).…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2017

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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.

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“…The environmental factors that are favorable for TC development are well documented and include warm sea surface temperatures (SSTs), moist conditions in midlevels, strong divergence in upper levels, weak vertical wind shear, and preexisting low-level cyclonic vorticity (e.g., Gray 1968;DeMaria et al 2001). It is known, however, that TCs also develop in environments with moderate to strong deep-layer vertical wind shear (e.g., Bracken and Bosart 2000;Davis and Bosart 2001, 2002, 2003 and over relatively cool SSTs (e.g., McTaggart-Cowan et al 2006). In fact, previous research has demonstrated that half of all TC developments over the North Atlantic occur in environments with moderate to strong baroclinicity and attendant vertical wind shear (e.g., McTaggart-Cowan et al 2008, 2013Hess et al 1995;Elsner et al 1996).…”

Section: Introductionmentioning

confidence: 99%

“…It is known, however, that TCs also develop in environments with moderate to strong deep-layer vertical wind shear (e.g., Bracken and Bosart 2000;Davis and Bosart 2001, 2002, 2003 and over relatively cool SSTs (e.g., McTaggart-Cowan et al 2006). In fact, previous research has demonstrated that half of all TC developments over the North Atlantic occur in environments with moderate to strong baroclinicity and attendant vertical wind shear (e.g., McTaggart-Cowan et al 2008, 2013Hess et al 1995;Elsner et al 1996). These baroclinically influenced TC developments encompass subtropical cyclones that undergo tropical transition (TT; e.g., Bosart 2003, 2004;Evans and Guishard 2009;Guishard et al 2009;Hulme and Martin 2009a,b) and precursor low-level cyclonic vorticity centers that interact with upper-tropospheric troughs (e.g., Sadler 1976Sadler , 1978Lander 1994;Molinari et al 1995;Chen et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Development of North Atlantic Tropical Disturbances near Upper-Level Potential Vorticity Streamers

Galarneau

McTaggart‐Cowan

Bosart

et al. 2015

Journal of the Atmospheric Sciences

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Tropical cyclone (TC) development near upper-level potential vorticity (PV) streamers in the North Atlantic is studied from synoptic climatology, composite, and case study perspectives. Midlatitude anticyclonic wave breaking is instrumental in driving PV streamers into subtropical and tropical latitudes, in particular near the time-mean midocean trough identified previously as the tropical upper-tropospheric trough. Twelve TCs developed within one Rossby radius of PV streamers in the North Atlantic from June through November 2004-08. This study uses composite analysis in the disturbance-relative framework to compare the structural and thermodynamic evolution for developing and nondeveloping cases.The results show that incipient tropical disturbances are embedded in an environment characterized by 850-200-hPa westerly vertical wind shear and mid-and upper-level quasigeostrophic ascent associated with the PV streamer, with minor differences between developing and nondeveloping cases. The key difference in synopticscale flow between developing and nondeveloping cases is the strength of the anticyclone north of the incipient tropical disturbance. The developing cases are marked by a stronger near-surface pressure gradient and attendant easterly flow north of the vortex, which drives enhanced surface latent heat fluxes and westward (upshear) water vapor transport. This evolution in water vapor facilitates an upshear propagation of convection, and the diabatically influenced divergent outflow erodes the PV streamer aloft by negative advection of PV by the divergent wind. This result suggests that the PV streamer plays a secondary role in TC development, with the structure and intensity of the synoptic-scale anticyclone north of the incipient vortex playing a primary role.

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A Global Climatology of Baroclinically Influenced Tropical Cyclogenesis

Cited by 78 publications

References 106 publications

Objective determination of the extratropical transition of tropical cyclones in the Northern Hemisphere

Objective determination of the extratropical transition of tropical cyclones in the Northern Hemisphere

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

Development of North Atlantic Tropical Disturbances near Upper-Level Potential Vorticity Streamers

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