Low-Level ZDR Signatures in Supercell Forward Flanks: The Role of Size Sorting and Melting of Hail

Dawson, Daniel T.; Mansell, Edward R.; Jung, Youngsun; Wicker, Louis J.; Kumjian, Matthew R.; Xue, Ming

doi:10.1175/jas-d-13-0118.1

Cited by 103 publications

(77 citation statements)

References 51 publications

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“…Dual-polarization observations have identified several previously unobserved features including the differential reflectivity (Z DR ) column, Z DR arc, r hv rings, and tornadic debris signature (TDS), among others (e.g., Illingworth et al 1987;Jameson et al 1996;Ryzhkov et al 2005;Romine et al 2008; Kumjian and Ryzhkov 2008;Palmer et al 2011;Snyder et al 2013;Dawson et al 2014;Kumjian et al 2014;Snyder and Bluestein 2014;Snyder et al 2015). Of the features listed above, the evolution of the TDS as manifest by the copolar cross-correlation coefficient (r hv ) is examined here in detail.…”

Section: Introductionmentioning

confidence: 94%

A Finescale Radar Examination of the Tornadic Debris Signature and Weak-Echo Reflectivity Band Associated with a Large, Violent Tornado

Houser

Bluestein

Snyder

2016

Monthly Weather Review

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High-resolution data of the tornadic debris signature (TDS) and weak-echo reflectivity band (WRB) associated with a large, violent tornado on 24 May 2011 in central Oklahoma are examined using a rapid-scan, X-band, polarimetric, mobile Doppler radar. Various characteristics of these features and their evolution are examined over time intervals of 20 s or less. The formation of the TDS, debris fallout, and inhomogeneities in the TDS structure, are analyzed from volumetric and single-elevation observations. Constant-radius vertical cross sections of Doppler velocity, reflectivity, and copolar cross-correlation coefficient are compared at various times during the tornado's life cycle; from them it is found that the weak echo column (WEC) is considerably narrower than the TDS and the WEC is confined to the strong gradient of Doppler velocities in the tornado's core. The TDS of the mature tornado extends radially outward, bound approximately by the 40 m s 21 radial isodop.Rapid-scan, near-surface data were collected for a period of 6 min, during which 2-s single-elevation PPI updates at 18 were available at heights below 100 m above radar level. During this period, a WRB associated with a visually observed horizontal vortex developed east of the tornado, along the leading edge of the secondary rear-flank gust front, as the tornado was rapidly intensifying. A relationship was noted between reduced radar-observed reflectivity and increased radar-observed radial convergence/divergence in the vicinity of the horizontal vortex as it strengthened. This feature is qualitatively analyzed and hypotheses explaining its generation and structure are discussed.

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Section: Introductionmentioning

confidence: 94%

A Finescale Radar Examination of the Tornadic Debris Signature and Weak-Echo Reflectivity Band Associated with a Large, Violent Tornado

Houser

Bluestein

Snyder

2016

Monthly Weather Review

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“…Figure 17 compares the simulated lag correlation with that observed during a supercell that occurred on 1 June 2008 in Oklahoma. This storm is selected because it was sampled with a polarimetric WSR-88D in ''rapid scan'' mode Dawson et al 2014). The peak lag correlation is found after about 23 min in the observations (r lag ' 0.8), although to facilitate comparison with the HUCM-simulated storm it has been shifted left by 8.8 min.…”

Section: Practical Implicationsmentioning

confidence: 99%

The Anatomy and Physics of ZDR Columns: Investigating a Polarimetric Radar Signature with a Spectral Bin Microphysical Model

Kumjian

Хаин

Benmoshe

et al. 2014

Journal of Applied Meteorology and Climatology

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155

127

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Polarimetric radar observations of deep convective storms frequently reveal columnar enhancements of differential reflectivity Z DR . Such ''Z DR columns'' can extend upward more than 3 km above the environmental 08C level, indicative of supercooled liquid drops being lofted by the updraft. Previous observational and modeling studies of Z DR columns are reviewed. To address remaining questions, the Hebrew University Cloud Model, an advanced spectral bin microphysical model, is coupled with a polarimetric radar operator to simulate the formation and life cycle of Z DR columns in a deep convective continental storm. In doing so, the mechanisms by which Z DR columns are produced are clarified, including the formation of large raindrops in the updraft by recirculation of smaller raindrops formed aloft back into the updraft at low levels. The internal hydrometeor structure of Z DR columns is quantified, revealing the transition from supercooled liquid drops to freezing drops to hail with height in the Z DR column. The life cycle of Z DR columns from early formation, through growth to maturity, to demise is described, showing how hail falling out through the weakening or ascending updraft bubble dominates the reflectivity factor Z H , causing the death of the Z DR column and leaving behind its ''ghost'' of supercooled drops. In addition, the practical applications of Z DR columns and their evolution are explored. The height of the Z DR column is correlated with updraft strength, and the evolution of Z DR column height is correlated with increases in Z H and hail mass content at the ground after a lag of 10-15 min.

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“…8a2, b2, c2, and d2). The size-sorting hypothesis, in which strongly veering wind shear in supercell environments advects raindrops from their source positions, was believed to result in a region of large drops along the southern edge of the forward flank downdraft (FFD) (e.g., Ryzhkov, 2008, 2009;Dawson et al, 2014).…”

Section: Flash Initiations In Supercells During the Tornadic Stagementioning

confidence: 99%

Characteristics of flash initiations in a supercell cluster with tornadoes

Zheng

MacGorman

2016

Atmospheric Research

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Flash initiations within a supercell cluster during 10-11 May 2010 in Oklahoma were investigated based on observations from the Oklahoma Lightning Mapping Array and the Norman, Oklahoma, polarimetric radar (KOUN). The flash initiations at positions dominated by graupel, dry snow, small hail and crystals accounted for 44.3%, 44.1%, 8.0% and 3.0% of the total flashes, respectively. During the tornadic stage of the southern supercell in the cluster, flash initiations associated with graupel occupied the main body, the right flank and the forward flank of the supercell, while those associated with dry snow dominated the outskirts of the adjacent forward anvil, right anvil and rear anvil. The flash initiations associated with small hail were concentrated around the main updraft, particularly toward its front side. Highly dense flash initiations were located in the regions overlying the differential reflectivity (Z DR ) arc and right anvil. The average initial height of the flashes decreased gradually from the rear to the front and from the right to the left flanks, while the height range over which initiations occurred reached a maximum at the front of the updraft. The flashes that were initiated in the adjacent forward anvils were largest on average, followed by those in the regions ahead of the updraft and near the Z DR arc. This study supports the concept of charge pockets and further deduces that the pockets in the right anvil are the most abundant and compact due to the frequent flash initiations, small-sized flashes and thin layers including flash initiations.

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Low-Level ZDR Signatures in Supercell Forward Flanks: The Role of Size Sorting and Melting of Hail

Cited by 103 publications

References 51 publications

A Finescale Radar Examination of the Tornadic Debris Signature and Weak-Echo Reflectivity Band Associated with a Large, Violent Tornado

A Finescale Radar Examination of the Tornadic Debris Signature and Weak-Echo Reflectivity Band Associated with a Large, Violent Tornado

The Anatomy and Physics of ZDR Columns: Investigating a Polarimetric Radar Signature with a Spectral Bin Microphysical Model

Characteristics of flash initiations in a supercell cluster with tornadoes

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