The Mechanism and Predictability of an Elevated Convection Initiation Event in a Weak-Lifting Environment in Central-Eastern China

Zhang, Murong; Meng, Zhiyong; Huang, Yipeng; Wang, Dongyong

doi:10.1175/mwr-d-18-0400.1

Cited by 21 publications

(36 citation statements)

References 48 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is a process in which a potentially unstable air parcel passes through its level of free convection (LFC) to initiate buoyant updraft growth with the release of instability. The ability to forecast when and where a new convective system will be initiated is important for disaster preparedness; therefore, CI has been extensively researched in recent decades (e.g., Campbell et al, ; Markowski et al, ; Peters & Hohenegger, ; Su & Zhai, ; Trier et al, ; Weckwerth & Parsons, ; Wilson & Roberts, ; Zhang et al, ; Ziegler & Rasmussen, ). However, predicting the precise location and timing of CI remains a challenge partly due to the lack of spatially and temporally dense observations, especially in the planetary boundary layer (PBL).…”

Section: Introductionmentioning

confidence: 99%

Convection Initiation Resulting From the Interaction Between a Quasi‐Stationary Dryline and Intersecting Gust Fronts: A Case Study

et al. 2019

Self Cite

View full text Add to dashboard Cite

This study explores the convection initiation (CI) of a high‐impact squall line that occurred in central eastern China on 3 June 2009 based on observations and numerical modeling. The CI occurred in a scenario in which a set of intersecting gust fronts, organized in a distinct scalloped pattern, propagated toward an area of enhanced moisture produced by a near‐surface convergence line. This convergence line developed in a quasi‐stationary dryline zone. The dryline primed the preconvective environment by deepening the moist layer prior to the arrival of the intersecting gust fronts. The onset of CI occurred approximately 30 min after these intersecting gust fronts passed through the CI location, which was on the dry side of the dryline. Although these gust fronts acted as a strong signal for CI potential, CI did not occur along the entire length of the scalloped pattern of the intersecting gust fronts. The exact locations of the initiated convective cells were at the vertices of the scalloped pattern. An idealized simulation using a cloud model was conducted, demonstrating that the vertex regions were characterized by more favorable dynamical conditions for CI compared to the nonvertex regions along the scalloped outflow boundary. The greater CI probability over the vertex region was attributed to the greater magnitudes and larger vertical and horizontal extents of updrafts.

show abstract

Section: Introductionmentioning

confidence: 99%

Convection Initiation Resulting From the Interaction Between a Quasi‐Stationary Dryline and Intersecting Gust Fronts: A Case Study

et al. 2019

Self Cite

View full text Add to dashboard Cite

show abstract

“…In this study, following the widely used MCS and CI definition based on radar reflectivity (Romatschke et al., 2010; Trier et al., 2017; Xiao et al., 2017; Zhang et al., 2019), the value of 40 dBZ is used as the reflectivity threshold for the convective precipitation; MCS is identified by a continuous or quasi‐continuous band of 40dBZ reflectivity that extends for at least 50 km in at least one direction; and CI is determined when and where the radar echo first reaches 40 dBZ.…”

Section: Data and Validationmentioning

confidence: 99%

“…Zhang et al. (2019) unveiled mechanisms of an elevated CI by analyzing the thermodynamic environment. They found that the existence of an elevated moist absolutely unstable layer was conducive to the elevated CI, but the dynamic mechanisms were not thoroughly discussed.…”

Section: Introductionmentioning

confidence: 99%

Initiation of an Elevated Mesoscale Convective System With the Influence of Complex Terrain During Meiyu Season

Zhang

Sun

2021

JGR Atmospheres

View full text Add to dashboard Cite

show abstract

“…In this subsection, we compare major features of atmospheric environment for CCs over the Korean peninsula with those for elevated MCSs over the central US (e.g., Moore et al 2003;Wilson and Roberts 2006;etc. ) and central East China (He et al 2018;Zhang et al 2019). Convection over the front in CCML events may be classified as elevated convection over the cold side of surface boundary.…”

Section: Major Features Of Atmospheric Environment For Ccs Over the Kmentioning

confidence: 99%

“…Recently, He et al (2018) found an occurrence of elevated convection in an event of a nocturnal squall line along the Meiyu Front over central East China, in which the main convection was initiated along a mesoscale convergence line above a stable boundary layer. Zhang et al (2019) showed an elevated MCS that was initiated ahead of a surface front without identifiable boundaries at the surface, and demonstrated that an elevated moist absolutely unstable layer (i.e., a saturated layer within which θ e decreases with height) was found to be conducive to the elevated CI.…”

Section: Introductionmentioning

confidence: 97%

Atmospheric Structure for Convective Development in the Events of Cloud Clusters over the Korean Peninsula

Lee

Shin

Park

2020

Asia-Pacific J Atmos Sci

View full text Add to dashboard Cite

This study examines atmospheric structures causing convective development in the events of cloud cluster (CC) over the Korean peninsula using the analysis and forecast data of National Centers for Environmental Prediction (NCEP) climate forecast system reanalysis (CFSR) and observation data. Two CC types-CCs associated with meso-α-scale lows (CCMLs) and mesoscale troughs (CCMTs)-were investigated. The common atmospheric structure for convective development in CC events is comprised of i) a strong southwesterly band (SWB; a region with southwesterly wind speeds >12.5 m s −1) in the lower troposphere upstream of CCs with a mesoscale convergence zone in its exit area, ii) a layer of high-θ e air in the lower troposphere near the surface extending from the southwest to SWB exit, iii) elevated height of maximum θ e in the lower troposphere near and over the convergence zone, above which a convectively unstable layer exists. Generality of the above-described structure has been demonstrated via examination of composite fields. SWB plays a major role in producing the structure for convective development in CC events over the Korean peninsula mainly through i) advection of high-θ e air from the southwest, and ii) significant horizontal convergence in the exit area, which can facilitate convection initiation. The two types of CC show notable differences in atmospheric structure across the boundary between high-θ e air from the southwest and low-θ e air in the northeast and in the mode of high-θ e air transport to the region of convective development. The boundary is generally tilted northeastward with height for CCML cases, whereas it is nearly vertical for the majority of CCMT cases. This study indicates that, despite the abovementioned differences, convective developments in both CC types can be considered as elevated convection that occurs as air parcels in an elevated layer of convective instability are lifted by upward motion in the convergence zone. For both types of CC, differential θ e advection plays the key role for the occurrence of elevated layer of convective instability. And θ e front in CCML events indicates the presence of elevated convective instability above it and the possibility of elevated convection provided that a lifting mechanism is available.

show abstract

The Mechanism and Predictability of an Elevated Convection Initiation Event in a Weak-Lifting Environment in Central-Eastern China

Cited by 21 publications

References 48 publications

Convection Initiation Resulting From the Interaction Between a Quasi‐Stationary Dryline and Intersecting Gust Fronts: A Case Study

Convection Initiation Resulting From the Interaction Between a Quasi‐Stationary Dryline and Intersecting Gust Fronts: A Case Study

Initiation of an Elevated Mesoscale Convective System With the Influence of Complex Terrain During Meiyu Season

Atmospheric Structure for Convective Development in the Events of Cloud Clusters over the Korean Peninsula

Contact Info

Product

Resources

About