Coordinated observations of sprites and in‐cloud lightning flash structure

Lu, Gaopeng; Cummer, Steven A.; Li, Jingbo; Zigoneanu, Lucian; Lyons, W. A.; Stanley, M. A.; Rison, W.; Krehbiel, P. R.; Thomas, Ronald J.; Beasley, William H.; Weiss, Stephanie A.; Blakeslee, Richard J.; Bruning, Eric C.; MacGorman, Donald R.; Meyer, Tiffany C.; Palivec, Kevin; Ashcraft, Thomas; Samaras, Tim

doi:10.1002/jgrd.50459

Cited by 82 publications

(191 citation statements)

References 109 publications

(211 reference statements)

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“…Parent CG for 00:27 sprite is marked by the big red '+'. also shows that the 00:23 sprite azimuth was horizontally displaced (16 and 4 km, respectively, and the time delay is about 45 ms) from the two +CGs, in agreement with results from Lu et al (2013) that sprites with a time delay of more than 20 ms mostly have a horizontal displacement of more than 20 km from their parent CGs (Fig. 14a in their paper).…”

Section: ° (A) -(H) Roi (Region Of Interest)supporting

confidence: 88%

“…The magnetic field measured by the ELF sensor would be the summation of the two +CGs. The CMC of CG is an important indicator for sprite initiation (Hu et al 2002;Lu et al 2013). According to the sprite QE heating theory in Pasko et al (1997), sprites are predicted to be initiated at about 75 km with a CMC of ~1000 C km (the charge of removal is 100 C, and the altitude is 10 km), and ~4000 C km (the altitude is also 10 km, but the charge of removal is 400 C) is needed for optical emissions at ~50 -70 km.…”

Section: ° (A) -(H) Roi (Region Of Interest)mentioning

confidence: 99%

“…The currently accepted theory of sprites is that they are caused by the quasi-electrostatic (QE) field produced by +CG in the troposphere (Pasko et al 1997;Liu et al 2015a). Observations further indicate that a large charge moment change (CMC) (defined as the product of the charge transferred by CG and the height from which it was removed, the main factor determining the magnitude of the QE field above the thundercloud) of cloud-toground lightning is necessary for sprite initiation (Hu et al 2002;Cummer and Lyons 2004;Li et al 2012;Lu et al 2012Lu et al , 2013.…”

Section: Introductionmentioning

confidence: 99%

“…Coordinated analysis made by Lu et al (2013) shows that sprite generation is 90% likely if a positive stroke occurs with impulse charge moment change (iCMC, defined as the product of the transferred charge within 2 ms after the return stroke and its original height above the ground) larger than 300 C km, more than three times lower than that in Hu et al (2002). The study of Hu et al (2002) also indicated that lightning CMC for sprite initiation can be as low as 120 C km and as high as 3070 C km, indicating that CMC for sprite production could span a wide range.…”

Section: Introductionmentioning

confidence: 99%

“…Coordinated analysis by Lu et al (2013) showed that multiple sprites with dancing features associated with a single lightning flash could be initiated either by distinct strokes of the flash, by a single stroke through a series of current surges superposed on an intense continuous current, or by both. Studies also show that in-cloud (IC) sprite-producing stroke activity could play a role in sprite formation (Ohkubo et al 2005; Van der Velde et al 2006;Marshall et al 2007;Asano et al 2009).…”

Section: Introductionmentioning

confidence: 99%

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Sprite possibly produced by two distinct positive cloud-to-ground lightning flashes

Yang¹,

Lu²,

Liu³

et al. 2017

Terr. Atmos. Ocean. Sci.

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Transient luminous event (TLEs) observations have been conducted in mainland China since 2007, with a number of TLEs documented. This study analyzed a very unusual and unique positive sprite event, that may be produced jointly by two distinct positive cloud-to-ground lightning flashes (+CGs) occurring within a short time difference but with different locations separated by about 27 km. This observation is different from previous studies reporting that most of the sprites were triggered by a single +CG flash and its possible following continuous current. Detailed analysis on extremely low frequency (ELF) magnetic field shows that combined charge moment change (CMC) due to the two +CGs is smaller (~1478 C km) than those of the parent CGs for the other two sprites (1582 and 2134 C km, respectively) recorded over the same thunderstorm. The vertical extension and brightness of the sprites correspond well with the CMC of their parent CGs, namely, the larger the CMC value the brighter the sprite, and the larger the CMC value the larger the vertical extension. Negative lightning flashes dominated during the thunderstorm life cycle. The three sprites occurred during a time window in which both negative and positive flashes were active. The three sprites occurred over the thunderstorm stratiform region.

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Section: ° (A) -(H) Roi (Region Of Interest)supporting

confidence: 88%

Section: ° (A) -(H) Roi (Region Of Interest)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Sprite possibly produced by two distinct positive cloud-to-ground lightning flashes

Yang¹,

Lu²,

Liu³

et al. 2017

Terr. Atmos. Ocean. Sci.

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Characteristics of positive cloud‐to‐ground lightning in Da Hinggan Ling forest region at relatively high latitude, northeastern China

Qie

Wang

et al. 2013

JGR Atmospheres

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[1] In 2009 and 2010, a multistation network of fast and slow antennas was installed on the edge of a relatively high latitude forest region in Da Hinggan Ling (50.4°N, 124.1°E) of northeastern China. The documented 185 positive cloud-to-ground (CG) flashes containing 196 return strokes were analyzed in the paper. It was found that 71.89% of the positive CG flashes contained continuing current. The average duration of continuing current was short with an arithmetic mean value of 33.29 ms and a geometric mean value of 16.74 ms; only one continuing current lasted longer than 150 ms, probably because of the small size of the storm cell in this relatively high latitude region. The vast majority (94.59%) of positive CG flashes was characterized by a single stroke, and the average number of stroke per flash is 1.06. The average charge transferred by positive stroke and continuing current, based upon the analysis of five flashes with well-documented simultaneous measurements of more than five stations, was +5.2 C from a height of 6.0 km (above ground) and +10.2 C from a height of 6.4 km, respectively. The charge moment for +CG strokes ranged from +13.7 C km to +55.9 C km, while that for continuing current ranged from +29.0 C km to +96.9 C km, respectively. The preliminary breakdown process in positive CG flashes can be classified into three types, namely type S (same), type D (different), and type C (chaotic) according to the disparities in the initial polarity of bipolar pulses from the return stroke, which account for 62.92%, 23.60%, and 13.48%, respectively. According to the electric field waveforms indicative (or not indicative) of intracloud (IC) discharge, positive CG flashes are classified into four types, i.e., ordinary positive CG flash (63.78%), hybrid +CG-IC flash (21.08%), hybrid IC-+CG flash (5.41%), and hybrid IC-+CG-IC flash (9.73%). About 15.14% of the recorded positive CG flashes were byproduct of IC lightning discharge.

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Bidirectional leader development in sprite‐producing positive cloud‐to‐ground flashes: Origins and characteristics of positive and negative leaders

et al. 2014

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Thirty-five sprite-producing lightning flashes were recorded in nine nights in different seasons at the east coast of Spain with a 3D Lightning Mapping Array (LMA) since July 2011. A low-frequency time-of-arrival network provided data on emissions from return strokes and intracloud processes and a very-high-frequency interferometer network produced complementary lightning data. This study analyzes the bidirectional development of flashes in order to understand the positioning and timing of the positive cloud-to-ground stroke (+CG) and its consequences for charge neutralization by negative leaders, affecting sprite morphology. A summary of negative leader extents, altitudes, and speeds before and after the + CG stroke is provided, as well as positive leader origins and inferred speeds. Negative leader speeds exhibited modes at 10 5 and 5 × 10 5 m s À1. Five examples with different evolutions are discussed: (1) Slow bidirectional development with negative leader termination before the + CG stroke; (2) Fast bidirectional development with the negative leader continuing after the + CG stroke. (3) Slow-fast bidirectional development with a negative leader exhibiting a sudden lowering and speed increase; (4) Fast secondary bidirectional development from an in-cloud horizontal positive leader. Negative leaders propagated rapidly into the upper positive charge layer, continuing after the + CG stroke; (5) Slow bidirectional development with a long negative leader (50 km) subject to cutoff while the original positive leader remained trapped inside negative charge. A + CG stroke subsequently occurred under the old negative leader channel. Carrot sprites tended to be associated with fast extending leaders after the stroke, columniform/mixed sprites with slower side branches.

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Coordinated observations of sprites and in‐cloud lightning flash structure

Cited by 82 publications

References 109 publications

Sprite possibly produced by two distinct positive cloud-to-ground lightning flashes

Sprite possibly produced by two distinct positive cloud-to-ground lightning flashes

Characteristics of positive cloud‐to‐ground lightning in Da Hinggan Ling forest region at relatively high latitude, northeastern China

Bidirectional leader development in sprite‐producing positive cloud‐to‐ground flashes: Origins and characteristics of positive and negative leaders

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