Meteorological Aspects of Gamma‐Ray Glows in Winter Thunderstorms

Wada, Yuuki; Enoto, T.; Kubo, Mamoru; Nakazawa, K.; Shinoda, Taro; Yonetoku, Daisuke; Sawano, Tatsuya; Yuasa, Takayuki; Ushio, Tomoo; Sato, Yousuke; Diniz, Gabriel; Tsuchiya, H.

doi:10.1029/2020gl091910

Cited by 27 publications

(42 citation statements)

References 45 publications

(55 reference statements)

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“…It is widely accepted, that the cloud charge structure for a typical thunderstorm contains an upper positive charge region consisting of ice crystals, a main negative charge region consisting of both graupel and ice crystals, and a lower positive charge region consisting of graupel (Kuettener, 1950). The electric charge of graupel is positive at temperatures warmer than -10° C, and negative at temperatures cooler than -10° C (Takahashi, 1978, Wada et al, 2021. In review (Williams, 1989) was stated that the tripolar structure of thunderstorms is supported by a wide variety of observations and that temperature appears to be the most important single parameter in controlling the polarity of charge acquired by the precipitation particles.…”

Section: Introductionmentioning

confidence: 99%

Structure of thunderstorm ground enhancements

et al. 2020

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The comparative analysis of three thunderstorms on Aragats in May 2021 demonstrates that relativistic runaway electron avalanches (RREAs) are developing in large areas of the thunderous atmosphere. In the active storm zone, RREAs last tens of seconds to a few minutes, until lightning flashes terminate electron acceleration. If the lightning activity is far from the detector site, the measured enhancements of particle fluxes (thunderstorm ground enhancements -TGEs) smoothly decay when the atmospheric conditions cannot anymore sustain the electron runaway process. In this case, the TGE has a more or less symmetrical shape and can last up to 10 minutes and more. Thus, RREAs development is paired with lightning activity, creating huge electron fluxes preceding the development of lightning leaders. We show that the total surface area exposed to ionizing radiation can reach 100 km 2 and the total number of gamma rays directed to the earth's surface -can be estimated as ≈1.3*10 16 (for TGE particles with energies above 300 KeV). The differential energy spectra of electrons and gamma rays recovered from the data of particle spectrometers are used to estimate the height of a strong accelerating electric field region, which can extend down to tens meters above the earth's surface.

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Section: Introductionmentioning

confidence: 99%

Structure of thunderstorm ground enhancements

et al. 2020

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“…The variations in the number of events by observation sites are shown in Figure 8. As mentioned in Wada et al [21], the largest number of gamma-ray glows were detected at site 5, Kanazawa University Kakuma Campus; 15 events for four years. The lower panel shows the normalized distribution by operational days.…”

Section: A Event Detectionmentioning

confidence: 64%

“…Among the 70 gamma-ray glows, 66 glows have a significance of more than 5σ, and the remaining 4 glows have less significance. Nineteen events have been reported in our previous publications [21][22][23][24]. There are simultaneous detections with nearby detectors (events 2 and 3 for example).…”

Section: A Event Detectionmentioning

confidence: 99%

Catalog of Gamma-ray Glows during Four Winter Seasons in Japan

Wada¹,

Matsumoto²,

Enoto³

et al. 2021

Preprint

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In 2015 the Gamma-Ray Observation of Winter Thunderstorms (GROWTH) collaboration launched a mapping observation campaign for high-energy atmospheric phenomena related to thunderstorms and lightning discharges. This campaign has developed a detection network of gamma rays with up to 10 radiation monitors installed in Kanazawa and Komatsu cities, Ishikawa Prefecture, Japan, where low-charge-center winter thunderstorms frequently occur. During four winter seasons from October 2016 to April 2020, in total 70 gamma-ray glows, minute-lasting bursts of gamma rays originating from thunderclouds, were detected. Their average duration is 58.9 sec. Among the detected events, 77% were observed in nighttime. The gamma-ray glows can be classified into temporally-symmetric, temporally-asymmetric, and lightning-terminated types based on their count-rate histories. An averaged energy spectrum of the gamma-ray glows is well fitted with a power-law function with an exponential cutoff, whose photon index, cutoff energy, and flux are 0.613 ± 0.009, 4.68 ± 0.04 MeV, and (1.013 ± 0.003) × 10 −5 erg cm −2 s −1 (0.2-20.0 MeV), respectively. The present paper provides the first catalog of gamma-ray glows and their statistical analysis detected during winter thunderstorms in the Kanazawa and Komatsu areas.

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“…We assume a cloud region with a quasi‐constant and homogeneous electric field to provide the electron accelerations and produce secondary gamma ray photons. Winter thunderstorms along the Sea of Japan, as gamma ray glow emitters, are thought to have a tripolar charge structure (Williams, 1989) as reported in the literature (Takahashi, 1978; Wada et al., 2021). Here we assume that the electric field region is formed between the negative charge and lower positive charge centers and thus electrons are accelerated downward.…”

Section: Simulation Setups and Methodology Of Analysismentioning

confidence: 92%

“…(1994) discovered Terrestrial Gamma ray Flashes (TGFs), which are microsecond‐lasting enhanced gamma ray bursts with energy reaching tens of MeV related with lightning discharges (Briggs et al., 2010; Smith et al., 2005; Tavani et al., 2011). A wide variaty of observations of other High Energy Atmospheric Phenomena (HEAP) (Babich, 2003) demonstrate interactions between the thundercloud electric field and high‐energy particles; including gamma ray glow (also called Thunderstorm Ground Enhancement, TGE and long bursts; Chilingarian, 2013; Wada et al., 2021), neutron bursts (Babich, 2019; Babich et al., 2007; Chilingarian, Bostanjyan, Karapetyan, & Vanyan, 2012; Chilingarian, Bostanjyan, & Vanyan, 2012; Martin & Alves, 2010; Shah et al., 1985; Shyam & Kaushik, 1999;) and TGFs afterglow (Diniz et al., 2018, 2021; Enoto et al., 2017; Rutjes & Ebert, 2017).…”

Section: Introductionmentioning

confidence: 99%

Atmospheric Electron Spatial Range Extended by Thundercloud Electric Field Below the Relativistic Runaway Electron Avalanche Threshold

et al. 2022

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Electric fields in thunderstorms are associated with enhanced energetic radiation emission previously detected in ground-based, airborne, and space experiments. 70 years after Wilson (1924) proposed such high-energy phenomenon in thunderstorms, Fishman et al. (1994) discovered Terrestrial Gamma ray Flashes (TGFs), which are microsecond-lasting enhanced gamma ray bursts with energy reaching tens of MeV related with lightning discharges (Briggs et al., 2010;Smith et al., 2005;Tavani et al., 2011). A wide variaty of observations of other High Energy Atmospheric Phenomena (HEAP) (Babich, 2003) demonstrate interactions between the thundercloud electric field and high-energy particles; including gamma ray glow (also called Thunderstorm Ground Enhancement, TGE and long bursts;

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Meteorological Aspects of Gamma‐Ray Glows in Winter Thunderstorms

Cited by 27 publications

References 45 publications

Structure of thunderstorm ground enhancements

Structure of thunderstorm ground enhancements

Catalog of Gamma-ray Glows during Four Winter Seasons in Japan

Atmospheric Electron Spatial Range Extended by Thundercloud Electric Field Below the Relativistic Runaway Electron Avalanche Threshold

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