The cloud flash‐to‐ground flash ratio and other lightning occurrence characteristics in Kathmandu thunderstorms

Baral, K. N.; Mackerras, D.

doi:10.1029/91jd02039

Cited by 20 publications

(15 citation statements)

References 21 publications

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“…7a and 7b that: (1) The first flash occurring in both types of thunderstorms is intra-cloud lightning (IC). The CG occurred later than the IC, and the frequency of the IC was higher than the CG, which is similar to the observation results (Mackerras, 1985;Baral and Mackerras, 1992). (2) The first flash of the clean thunderstorm occurs in 15th minutes, and most flashes occur in 15th minutes to 40th minutes.…”

Section: Lightning Dischargessupporting

confidence: 86%

A Numerical Study of the Effects of Aerosol on Electrification and Lightning Discharges in Thunderstorms

Tan

Chun-Yan

et al. 2017

Chinese J of Geophysics

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Based on existing three‐dimensional (3‐D) thunderstorm electrification and discharge model, this work coupled with a classical parameterization scheme of aerosol activation is used to simulate a case of tropical convection in Changchun. The study shows that the change of aerosol concentration has an important influence on the microphysics, electrification and discharge processes of thunderstorm clouds. The results show that: (1) As the aerosol concentration increases in the polluted thunderclouds, the increase of the number of cloud droplets and the updraft cause the increase of the number of ice crystal and graupel, but the decrease of the scale; (2) Compared to the clean thunderclouds, the non‐induced electrification process is weak, while the induction electrification process is strong, and the duration of electrification become longer in polluted thunderclouds; (3) The first charge time of the polluted thunderclouds delays, but the total lightning frequency increases and duration is longer. Meanwhile, the frequency of the cloud‐to‐ground flash in the polluted thunderclouds increases, and the increase of the positive cloud‐to‐ground flash is more obvious.

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Section: Lightning Dischargessupporting

confidence: 86%

A Numerical Study of the Effects of Aerosol on Electrification and Lightning Discharges in Thunderstorms

Tan

Chun-Yan

et al. 2017

Chinese J of Geophysics

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“…We have also attempted to find whether the proportion was related to ground flash or total flash activity on a daily basis. The instrument used to detect the different types of lightning is denoted CGR3 and has been described by Mackerras [1985], Mackerras and Darveniza [1986, 1992] and Baral and Mackerras [1992]. The method used to detect positive ground flashes is described in detail below, as the accuracy of the results obtained depends on the appropriateness of the method.…”

mentioning

confidence: 83%

Positive cloud‐to‐ground lightning discharges in Kathmandu thunderstorms

Baral¹,

Mackerras²

1993

J. Geophys. Res.

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The occurrence of positive cloud‐to‐ground lightning discharges in thunderstorms in the vicinity of Kathmandu, Nepal (27.4°N, 85.2°E) has been recorded during the 21‐month period from March 1987 to November 1988 inclusive, using the daily registrations of a CGR3 lightning flash counter that provided records of the approximate numbers of positive ground flashes, negative ground flashes, and cloud flashes, with effective ranges of about 12 km for cloud flashes, 14 km for negative ground flashes, and 16 km for positive ground flashes. The detection of positive ground flashes was based on the presence of a relatively large negative‐going step in the electric field change caused by the positive return stroke in the discharge. It was found that the overall mean proportion of positive ground flashes to all ground flashes was 0.28, and that the overall mean positive ground flash density was 0.6 km−2 yr−1. The uncertainty in these values is about ±50%. The proportions of positive ground flashes in three of the climatic periods in the year were 0.26 in the premonsoon period (February to May inclusive), 0.34 in the monsoon period (June to August inclusive), and 0.38 in the postmonsoon period (September to November inclusive). This apparent increase in the proportion is accompanied by a seasonal decline in electrical activity, the premonsoon period being the most active, and the postmonsoon the least active. The increase also appears to be associated with a decrease in the proportion of cloud flashes to total flashes. The proportion of positive ground flashes is larger than is observed in most low‐altitude tropical and subtropical sites but is smaller than that observed in winter thunderstorms at some higher‐latitude sites. Possible reasons for the relatively high rate of occurrence of positive ground flashes (unsupported by concurrent atmospheric soundings) are the site altitude, thundercloud charge heights, vertical wind shear and the mountainous nature of the terrain.

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“…The capabilities of the CGR3 have been described by Mackerras [1985] and Mackerras and Darveniza [1992]. The results of the survey were reported by Mackerras andDarveniza [1992, 1994], and reports for specific locations were given for Tel-Aviv [Fair and Levin, 1994], Katmandu, Nepal [Baral and Mackerras, 1992], and Gaborone, Botswana [dayarante and Ramachandran, 1996].…”

Section: Data Acquisitionmentioning

confidence: 99%