Evolution of convective characteristics during tropical cyclogenesis

Kilroy, Gerard

doi:10.1002/qj.4011

Cited by 6 publications

(2 citation statements)

References 67 publications

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“…Although the absolute mass flux of shallow convective clouds with maximum MFH below 2 km is small (See Figure S1), they occur most frequently over the domain. Some studies showed that the shallow cumulus convection plays an important role in TC formation (Wang, 2014) and intensification (Kilroy, 2021). Due to the high frequency of occurrence, the parameterization for shallow convective clouds should be paid more attentions.…”

Section: Composite Analysis By Maximum Mass Flux Heightmentioning

confidence: 99%

Statistics of the Subgrid Cloud of an Idealized Tropical Cyclone at Convection‐Permitting Resolution

Zhang

Bao

Huang

et al. 2023

J Adv Model Earth Syst

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The clouds in a tropical cyclone (TC) exhibit a large variety of processes and forms due to the underlying vortex dynamics. For physically realistic numerical simulations of TCs, the cloud processes must be adequately resolved or parameterized. Current operational numerical weather prediction (NWP) models for TC simulation and forecasting have a horizontal grid size on the order of 1 km, which is convection-permitting but not sufficient to resolve individual convective cells fully (e.g., Bryan et al., 2003;Moeng et al., 2010). Including subgrid parameterization of convection in the physics configuration is a practical means to account for the effect of unresolved convection on the resolved TC dynamics.For practical uses in NWP models, scale-adaptive algorithms of convective mass flux have been introduced into traditional quasi-equilibrium convection parameterization schemes that can be used at convection-permitting resolutions (

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Section: Composite Analysis By Maximum Mass Flux Heightmentioning

confidence: 99%

Statistics of the Subgrid Cloud of an Idealized Tropical Cyclone at Convection‐Permitting Resolution

Zhang

Bao

Huang

et al. 2023

J Adv Model Earth Syst

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“…Rotation of sub‐severe storms—those not meeting National Weather Service severe weather criteria—has apparently not been studied at all. VHTs are beginning to be observed through geostationary satellites and in some aircraft observations (Hogsett & Stewart, 2014) but most effort at understanding these uses regional simulations, and exclusively in the context of mature and intensifying tropical cyclones where there has been some effort to better understand their role in genesis and intensification (Kilroy, 2021, and references therein; Wang, 2018; Zawislak, 2020, and references therein; Hendricks et al., 2004). An appreciation for rotating updrafts elsewhere is virtually absent.…”

Section: Introductionmentioning

confidence: 99%

A Global Survey of Rotating Convective Updrafts in the GFDL X‐SHiELD 2021 Global Storm Resolving Model

et al. 2023

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We present the global characteristics of rotating convective updrafts in the 2021 version of GFDL's eXperimental System for High‐resolution prediction on Earth‐to‐Local Domains (X‐SHiELD), a kilometer‐scale global storm resolving model (GSRM). Rotation is quantified using 2–5 km Updraft Helicity (UH) in a year‐long integration forced by analyzed SSTs. Updrafts with UH magnitudes above 50 m2 s−2 are common over the mid‐latitude continents, where they are associated with severe weather especially in the warm seasons but are also common over most tropical ocean basins. In nearly all areas cyclonically rotating convection dominates, with larger UH values increasingly preferring cyclonic rotation. The ratio of cyclonic to anticyclonic updrafts is largest in the subtropical and mid‐latitude oceans and is slightly lower over mid‐latitude continents. The ratio of cyclonic to anticyclonic updrafts can be substantively explained by the mean storm‐relative helicity (SRH) in convective regions, indicating the importance for environmental controls on the sense of storm rotation, although internal storm dynamics also plays a role in the generation of anticyclonic updrafts.

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A Global Survey of Rotating Convective Updrafts in the GFDL X-SHiELD 2021 Global Storm Resolving Model

Harris

Zhou

Kaltenbaugh³

et al. 2022

Preprint

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Thunderstorm updrafts are sometimes observed to rotate. This is well-understood in the context of severe weather in continental convection, especially over the contiguous United States (CONUS), for example, Kain et al. (2008). More recently the role of vortical hot towers (VHTs;Guimond et al., 2010;Hendricks et al., 2004) in tropical cyclone intensity changes has become better understood. But updraft rotation is typically studied in isolated events, and it has not been considered as a broadly distributed phenomenon. This is in part due to the lack of observations of rotating convection. Indeed, the frequency of strongly rotating updrafts-especially mesocyclones-even in the CONUS was poorly understood before the installation of a dense nationwide Doppler radar network, as seen through the increases in radar-detected tornadoes after 1990 (Verbout et al., 2006) and improved understanding that most mesocyclones are not associated with tornadoes (Trapp et al., 2005). The spatial distribution of rotating updrafts has been scarcely studied except as for its role in creating severe weather, specifically supercell thunderstorms, mesoscale convective systems (MCSs), and tornadoes. Rotation of sub-severe storms-those not meeting National Weather Service severe weather criteria-has apparently not been studied

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Evolution of convective characteristics during tropical cyclogenesis

Cited by 6 publications

References 67 publications

Statistics of the Subgrid Cloud of an Idealized Tropical Cyclone at Convection‐Permitting Resolution

Statistics of the Subgrid Cloud of an Idealized Tropical Cyclone at Convection‐Permitting Resolution

A Global Survey of Rotating Convective Updrafts in the GFDL X‐SHiELD 2021 Global Storm Resolving Model

A Global Survey of Rotating Convective Updrafts in the GFDL X-SHiELD 2021 Global Storm Resolving Model

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