Upper-Tropospheric Precursors to the Formation of Subtropical Cyclones that Undergo Tropical Transition in the North Atlantic Basin

Bentley, Alicia M.; Bosart, Lance F.; Keyser, Daniel

doi:10.1175/mwr-d-16-0263.1

Cited by 27 publications

(26 citation statements)

References 42 publications

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“…In case of the RCM‐modelled STCs, the distribution is similar to the observed values, as there is a distinct prevalence of STCs over winter months, although the observed March peak is not reproduced in the simulations. The higher prevalence in winter months gives support to the fact that the simulated STCs mainly develop from extratropical precursors, a relationship shown in observational studies (González‐Alemán et al, , Evans and Guishard, , Guishard et al, , Bentley et al, , ). Extratropical precursors such as upper‐level troughs and cut‐off lows are more likely to reach the subtropical domain in winter as the southern edge of the upper‐level midlatitude circulation is located at its southernmost position.…”

Section: Rcms Nested In Gcms In the Historical Period (1951–2000)mentioning

confidence: 87%

“…As STCs have strong connections to the atmospheric dynamics in the extratropics and subtropics (they form from extratropical precursors; Evans and Guishard, 2009; * Correspondence to: J. J. González-Alemán, Environmental Sciences Institute, University of Castilla-La Mancha, Avenida Carlos III, s/n, Toledo 45071, Spain. E-mail: juanjesus.gonzalez@uclm.es González-Alemán et al, 2015;Bentley et al, 2017) and to the ocean in their lower boundary (through sea surface temperatures (SSTs) or warm-air advections) González-Alemán et al, 2015), it is worth researching if anthropogenic climate change (ACC) could cause changes in their formation. Alterations in the atmospheric patterns over the extratropics and subtropics projected for future climate conditions (Thorne et al, 2011;Vavrus, 2012, 2015) as well as alterations in SSTs distribution (Collins et al, 2013) may lead to changes in their frequency of occurrence, location and/or intensity.…”

Section: Introductionmentioning

confidence: 99%

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Subtropical cyclones near‐term projections from an ensemble of regional climate models over the northeastern Atlantic basin

González-Alemán

Gaertner

Sánchez

et al. 2017

Intl Journal of Climatology

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Since nearly a decade ago, hybrid cyclones called subtropical cyclones (STCs) have attracted the attention of scientific and forecasting community due to their identification as damaging weather systems. Research about them has been so far focused on present climate data. A study of STCs under future climate scenarios has not been performed yet. For the first time, in this work we analyse the capability of regional climate models (RCMs) to simulate STCs in addition to searching for possible alterations in their frequency and intensity due to anthropogenic climate change over the subtropical northeastern Atlantic basin. By using an ensemble of three RCMs nested in four different global climate models (GCMs), we find that RCMs acceptably reproduce STCs (except for certain model combinations) for the historical climate period (1951–2000), giving support for the analysis of future climate results. In pure GCM simulations, no STCs are identified. For future climate conditions under A1B, A2 and B1 scenarios (2001–2050), more simulations indicate a decrease in the frequency of STCs than those which find an increase. This decrease is showed to be partially due to a reduced presence of extratropical cyclones, from which they tend to form, within that region. However, no strong agreement between simulations has been obtained, and other factors like the changes in the conversion rate could affect STCs in the future. With respect to intensity, no clear tendency is found.

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Section: Rcms Nested In Gcms In the Historical Period (1951–2000)mentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Subtropical cyclones near‐term projections from an ensemble of regional climate models over the northeastern Atlantic basin

González-Alemán

Gaertner

Sánchez

et al. 2017

Intl Journal of Climatology

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“…It has been reported that a cut-off low or stratospheric PV streamer in the upper troposphere associated with anticyclonic Rossby wave breaking (Martius et al, 2007;Waugh & Polvani, 2000;Wernli & Sprenger, 2007) can initiate organized deep convection (e.g., Waugh & Funatsu, 2003) and a subtropical cyclone (e.g., Galarneau et al, 2015) by destabilizing the troposphere (Juckes & Smith, 2000) or through QG forcing for ascent (Hoskins et al, 1985;Trenberth, 1978). Some of these subtropical cyclones occasionally develop into TCs as they travel across a warm SST region (Bentley et al, 2017).…”

Section: Evolution Of the Upper Tropospheric Disturbancementioning

confidence: 99%

“…Alternatively, the colder and drier air transported into the upper troposphere serves to destabilize the tropospheric column by enhancing convective available potential energy (CAPE), thus to foster convectively favorable environments (Juckes & Smith, 2000). The associated anticyclonic wave breaking (and PV streamer) over the tropical eastern Pacific and North Atlantic has been attributed to the formation of subtropical cyclones, which can subsequently undergo tropical transition (Bentley et al, 2017;Bentley & Metz, 2016;Davis & Bosart, 2003Galarneau et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

The Tropical Transition in the Western North Pacific: The Case of Tropical Cyclone Peipah (2007)

Chang

Chan

et al. 2019

JGR Atmospheres

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This study examines the transition of an extratropical disturbance to a tropical cyclone (TC), Peipah (2007), in the western North Pacific (WNP), using reanalysis and geostationary satellite data. Instead of regular diurnal fluctuations of deep convection, the pre‐TC disturbance accompanies deep convection only for short durations every other day. When the pre‐TC vorticity is traced back to 7 days prior to its formation, the traced‐back vorticity indicates a strong potential vorticity (PV) trough in the subtropical upper troposphere that originated from the midlatitude lower stratosphere. The quasi‐geostrophic forcing and reduced static stability at the leading edge of the PV trough result in the formation of an extratropical disturbance. The vertical structure of the extratropical disturbance shows maximum vorticity in the upper troposphere and cold temperature anomaly within it throughout the entire troposphere. As the extratropical disturbance moved into the tropical WNP, deep convection associated with quasi‐geostrophic dynamics over the warm ocean initiated tropical transition of the extratropical disturbance to a TC through diabatic redistribution of PV in the tropospheric column as well as transition of the cold anomaly into a warm anomaly within the vortex. With additional contribution of barotropic energy conversion in the lower troposphere, the warm‐core low system finally developed into a TC‐strength vortex. These results indicate that PV troughs of the stratospheric origin over the subtropical Pacific Ocean can contribute to TC formations in the WNP.

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“…The midlatitude wave teleconnection is stronger in regime 4 compared to regime 5, while the anomalous ridge is seen to retrograde southwestwards leading to significant positive pressure anomalies in the upper‐troposphere over the southwest United States and negative anomalies over the southeast for regime 6. This sequence of upper‐tropospheric configurations is reminescent of the behaviour of potential vorticity (PV) ‘streamers’ during anticyclonic wave breaking (Thorncroft et al ., ; Davis, ) and which have been related to subtropical cyclone formation in the North Atlantic in previous works (Bentley, ). PV streamers inject regions of relatively high upper‐tropospheric PV into the subtropical lower troposphere, which become advected westward by the mean easterlies and CLLJ during the sequence of regimes 4–6.…”

Section: Propagating Convective Cellsmentioning

confidence: 99%

Convection regimes and tropical‐midlatitude interactions over the Intra‐American Seas from May to November

Vigaud

Robertson

2017

Intl Journal of Climatology

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A cluster analysis is applied to National Oceanic and Atmospheric Administration daily outgoing longwave radiation anomaly fields over the Intra‐American Seas, for the May to November rainy season 1980–2009. Seven recurrent convection regimes are identified, each with distinct impacts on local rainfall. Three suppressed‐convection regimes prevailing throughout the season and in particular during the Mid‐Summer Drought are related to transient anticyclonic circulation anomalies and broad drying over the region. The remaining regimes are all related to enhanced convection and cyclonic circulation anomalies over the Caribbean. For one wet regime, the cyclonic anomaly is located over Central America, which increases moisture advection from the eastern Pacific and in turn rainfall over Central and South America to the disadvantage of northern regions of the Caribbean. The three other regimes are associated with a weaker Caribbean Low Level Jet along its southern branch stretching along the South American coast, while its northern branch is strengthened, exposing the Caribbean to more moisture advection from the northeast trade winds, enhancing convection and rainfall locally. These three wet regimes are related to northwestward‐propagating convective cells that can be traced in a composite sense to the southward incursion of baroclinic waves from the midlatitudes, and anticyclonic wave breaking. In addition, their frequencies are found to be higher during phases 1 and 2 of the Madden‐Julian Oscillation, suggesting a connection with easterly waves emanating from African convection. Relationships are shown between these three northwestward‐propagating wet regimes and historical floods in the Caribbean illustrating the potential value of the convective regime approach for ultimately improving regional predictions and disaster early warning on sub‐seasonal scales.

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Upper-Tropospheric Precursors to the Formation of Subtropical Cyclones that Undergo Tropical Transition in the North Atlantic Basin

Cited by 27 publications

References 42 publications

Subtropical cyclones near‐term projections from an ensemble of regional climate models over the northeastern Atlantic basin

Subtropical cyclones near‐term projections from an ensemble of regional climate models over the northeastern Atlantic basin

The Tropical Transition in the Western North Pacific: The Case of Tropical Cyclone Peipah (2007)

Convection regimes and tropical‐midlatitude interactions over the Intra‐American Seas from May to November

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