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1. Continuous Initial Breakdown Development of In‐Cloud Lightning Flashes

   https://doi.org/10.1029/2024JD041302  

   Pu, Yunjiao; Cummer, Steven A (October 2024, Journal of Geophysical Research: Atmospheres)

   Abstract Using a 30–250 MHz VHF interferometer, we observed a previously unreported mode of initial lightning development inside thunderclouds. This mode is defined by continuous VHF radiation spanning several km within the first few milliseconds of lightning initiation. Following flash initiation through fast positive breakdown at high altitudes above 9 km, the VHF radiation front of upward negative streamers ascended continuously at a speed of ∼1.0 × 10⁶ m/s, forming a continuous initial breakdown burst (CIBB) about 2 km in length. For the two CIBBs analyzed, the long and narrow CIBB channel was traversed by dart leaders that occurred later in the flash, indicating that the CIBB channel belongs to what becomes the main conducting leader channel. In contrast to classic initial breakdown pulses (IBPs) with sub‐pulses superimposed on the rising edge, CIBBs produced a series of discrete, narrow LF pulses (<10 μs) with an average time interval of 0.20 and 0.14 ms, respectively. We speculate that a CIBB is a continuously developing negative streamer system in the high electric field region at high altitudes, with connections of internal plasma channels producing LF pulses. These results have implications for physical conditions conducive to the formation of a long and continuous negative streamer system. 

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2. Observations of the Origin of Downward Terrestrial Gamma‐Ray Flashes

   https://doi.org/10.1029/2019JD031940  

   Belz, J. W.; Krehbiel, P. R.; Remington, J.; Stanley, M. A.; Abbasi, R. U.; LeVon, R.; Rison, W.; Rodeheffer, D.; Abu‐Zayyad, T.; Allen, M.; et al (October 2020, Journal of Geophysical Research: Atmospheres)

   null (Ed.)

   Abstract In this paper we report the first close, high-resolution observations of downward-directed terrestrial gamma-ray flashes (TGFs) detected by the large-area Telescope Array cosmic ray observatory, obtained in conjunction with broadband VHF interferometer and fast electric field change measurements of the parent discharge. The results show that the TGFs occur during strong initial breakdown pulses (IBPs) in the first few milliseconds of negative cloud-to-ground and low-altitude intracloud flashes, and that the IBPs are produced by a newly-identified streamer-based discharge process called fast negative breakdown. The observations indicate the relativistic runaway electron avalanches (RREAs) responsible for producing the TGFs are initiated by embedded spark-like transient conducting events (TCEs) within the fast streamer system, and potentially also by individual fast streamers themselves. The TCEs are inferred to be the cause of impulsive sub-pulses that are characteristic features of classic IBP sferics. Additional development of the avalanches would be facilitated by the enhanced electric field ahead of the advancing front of the fast negative breakdown. In addition to showing the nature of IBPs and their enigmatic sub-pulses, the observations also provide a possible explanation for the unsolved question of how the streamer to leader transition occurs during the initial negative breakdown, namely as a result of strong currents flowing in the final stage of successive IBPs, extending backward through both the IBP itself and the negative streamer breakdown preceding the IBP. 

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3. Intermediate Fluence Downward Terrestrial Gamma Ray Flashes as Observed by the Telescope Array Surface Detector

   https://doi.org/10.1029/2024JD041260  

   Abbasi, R U; Kieu, N; Krehbiel, P R; Belz, JW; Saba, M_M F; Rison, W; Stanley, M A; Rodeheffer, D; Mazzucco, D; Knight, T; et al (December 2024, Journal of Geophysical Research: Atmospheres)

   Abstract On 11 September 2021, two small thunderstorms developed over the Telescope Array Surface Detector (TASD) that produced an unprecedented number of six downward terrestrial gamma ray flashes (TGFs) within one‐hour timeframe. The TGFs occurred during the initial stage of negative cloud‐to‐ground flashes whose return strokes had increasingly large peak currents up to 223 kA, 147 GeV energy deposit in up to 25 1.2 km‐spaced surface detectors, and intermittent bursts of gamma‐rays with total durations up to 717 s. The analyses are based on observations recorded by the TASD network, complemented by data from a 3D lightning mapping array, broadband VHF interferometer, fast electric field change sensor, high‐speed video camera, and the National Lightning Detection Network. The TGFs of the final two flashes had gamma fluences of and 8, logarithmically bridging the gap between previous TASD and satellite‐based detections. The observations further emphasize the similarity between upward and downward TGF varieties, suggesting a common mechanism for their production. 

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4. Polarity Asymmetries in Rocket‐Triggered Lightning

   https://doi.org/10.1029/2023GL105041  

   da_Silva, C L; Winn, W P; Taylor, M C; Aulich, G D; Hunyady, S J; Eack, K B; Edens, H E; Sonnenfeld, R G; Krehbiel, P R; Eastvedt, E M; et al (September 2023, Geophysical Research Letters)

   Abstract The dissonant development of positive and negative lightning leaders is a central question in atmospheric electricity. It is also the likely root cause of other reported asymmetries between positive and negative lightning flashes, including the ones regarding: stroke multiplicity, recoil activity, leader velocities, and emission of energetic radiation. In an effort to contrast lightning leaders of different polarities, we highlight the staggering differences between two rocket‐triggered lightning flashes. The flash beginning with upward positive leaders exhibits an initial continuous current stage followed by multiple sequences of dart leaders and return strokes. On the other, in its opposite‐polarity counterpart, the upward development of negative leaders is by itself the entire flash. As a result, the flash with negative leaders is faster, briefer, transfers less charge to the ground, has lower currents, and smaller spatial extent. We conclude by presenting a discussion on the three fundamental leader propagation modes. 

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5. Typical Winter TGF Lightning: Vertical Negative Leader Progression Features and Charge Structures

   https://doi.org/10.1029/2024GL114087  

   Yang, Qingliu; Wang, Daohong; Wu, Ting; Smith, David M; Wada, Yuuki; Nakazawa, Kazuhiro; Kamogawa, Masashi (September 2025, Geophysical Research Letters)

   Abstract We have studied the vertical negative leader progression features and the charge structures of 13 typical winter lightning flashes that produced downward terrestrial gamma‐ray flashes (TGFs). All these flashes started at altitudes below 1.5 km with an initial downward negative leader that propagates at a speed ranging from 1.3 to 4.5 × 10⁶ m/s, followed by a strong negative return stroke called “energetic compact stroke” (ECS). After the ECS, usually there exists a radio quiet period lasting more than 10 ms. Interestingly, for more than half of the cases, soon after the resumed activities, an upward negative leader occurred at a position close to the lightning initiation point. Most of TGF lightning occurred under a main negative charge layer at the height of around 2 km. This negative charge layer is usually featured with a thickness of less than 2 km and a horizontal extension of more than 10 km. 

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