FORTE observations of simultaneous VHF and optical emissions from lightning: Basic phenomenology

Suszcynsky, D. M.; Kirkland, Matt W.; Jacobson, A. R.; Franz, R. C.; Knox, S.O.; Guillen, J. L. L.; Green, J. L.

doi:10.1029/1999jd900993

Cited by 80 publications

(128 citation statements)

References 30 publications

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“…Further observations on NBEs and their associated VHF TIPPs were presented in publications based on FORTE (Jacobson, 2003a, b;Jacobson and Light, 2003;) and on LASA Jacobson et al, 2007;Suszcynsky and Heavner, 2003;Wiens et al, 2008). Recently it has been shown that the VHF pulse in the TIPP associated with NBEs is neither polarized nor coherent (Jacobson et al, 2011).…”

Section: A R Jacobson and T E L Light: Revisiting "Narrow Bipolamentioning

confidence: 96%

“…This ground-truth campaign allowed 392 A. R. Jacobson and T. E. L. Light: Revisiting "Narrow Bipolar Event" intracloud lightning the unambiguous identification of radio signatures that are characteristic of various stroke types (positive and negative cloud-to-ground, or +CG and −CG; intracloud, or IC; etc.). This ground-truthing by NLDN allowed development of a rudimentary identification of stroke type from the FORTErecorded radio waveform alone (Suszcynsky et al, 2000).…”

Section: Data Resources For This Studymentioning

confidence: 99%

“…These sferics were sampled over several millisec, with a sampling rate of 1 Megasamples/s. These waveform recordings were extremely useful for studying characteristics of lightning discharges, including NBEs Jacobson and Heavner, 2005;Jacobson et al, 2007;Smith et al, , 2004Suszcynsky and Heavner, 2003). Indeed, the only completely reliable way of identifying a sferic as being due to an NBE is to examine details of its recorded waveform from several stations.…”

Section: Data Resources For This Studymentioning

confidence: 99%

“…This particular dual-channel receiver system was in full operation by December 1997; it failed in December 1999, after which FORTE used a single-channel, 85-MHz-bandwidth receiver. More details are available elsewhere Jacobson and Shao, 2002;Shao et al, , 2005Jacobson, 2001, 2002;Suszcynsky et al, 2000).…”

Section: Data Resources For This Studymentioning

confidence: 99%

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Revisiting "Narrow Bipolar Event" intracloud lightning using the FORTE satellite

Jacobson

Light

2012

Ann. Geophys.

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Abstract. The lightning stroke called a "Narrow Bipolar Event", or NBE, is an intracloud discharge responsible for significant charge redistribution. The NBE occurs within 10-20 µs, and some associated process emits irregular bursts of intense radio noise, fading at shorter timescales, sporadically during the charge transfer. In previous reports, the NBE has been inferred to be quite different from other forms of lightning strokes, in two ways: First, the NBE has been inferred to be relatively dark (non-luminous) compared to other lightning strokes. Second, the NBE has been inferred to be isolated within the storm, usually not participating in flashes, but when it is in a flash, the NBE has been inferred to be the flash initiator. These two inferences have sufficiently stark implications for NBE physics that they should be subjected to further independent test, with improved statistics. We attempt such a test with both optical and radio data from the FORTE satellite, and with lightning-stroke data from the Los Alamos Sferic Array.We show rigorously that by the metric of triggering the PDD optical photometer aboard the FORTE satellite, NBE discharges are indeed less luminous than ordinary lightning. Referred to an effective isotropic emitter at the cloud top, NBE light output is inferred to be less than ∼3 × 10 8 W.To address isolation of NBEs, we first expand the pool of geolocated intracloud radio recordings, by borrowing geolocations from either the same flash's or the same storm's other recordings. In this manner we generate a pool of ∼2 × 10 5 unique and independent FORTE intracloud radio recordings, whose slant range from the satellite can be inferred. We then use this slant range to calculate the Effective Radiated Power (ERP) at the radio source, in the passband 26-49 MHz. Stratifying the radio recordings by ERP into eight bins, from a lowest bin (<5 kW) to a highest bin (>140 kW), we document a trend for the radio recordings to become more isolated in time as the ERP increases. The highest ERP bin corresponds to the intracloud emissions associated with NBEs.At the highest ERP, the only significant probability of temporal neighbors is during times following the high-ERP events. In other words, when participating in a flash, the high-ERP emissions occur at the apparent flash initiation.

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Section: A R Jacobson and T E L Light: Revisiting "Narrow Bipolamentioning

confidence: 96%

Section: Data Resources For This Studymentioning

confidence: 99%

Section: Data Resources For This Studymentioning

confidence: 99%

Section: Data Resources For This Studymentioning

confidence: 99%

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Revisiting "Narrow Bipolar Event" intracloud lightning using the FORTE satellite

Jacobson

Light

2012

Ann. Geophys.

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“…A combination of an ELF electrical/magnetic detection with another type (most obviously an optical sensor, but possibly gamma ray, or even VHF radio) would be much more compelling (as performed on FORTE and C/NOFS at Earth-see, e.g., Fig. 5) and Suszcynsky et al 2000. As noted by Russell (2011), a low circular polar orbit is desirable for radar mapping, and a modest lightning instrument would be a valuable but relatively inexpensive augmentation to a radar mapping mission.…”

Section: Conclusion and Recommendations For Future Surveysmentioning

confidence: 99%

Lightning detection on Venus: a critical review

Lorenz

2018

Prog Earth Planet Sci

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Claimed detections and nondetections of lightning and related electromagnetic emissions on Venus are qualitatively contradictory. Here, motivated by the commencement of observations by the Akatsuki spacecraft and by studies of future missions, we critically review spacecraft and ground-based observations of the past 40 years, in an attempt to reconcile the discordant reports with a minimal number of assumptions. These include invoking alternative interpretations of individual reports, guided by sensitivity thresholds, controls, and other objective benchmarks of observation integrity. The most compelling evidence is in fact the first, the very low frequency (VLF) radio emissions recorded beneath the clouds by all four of the Veneras 11-13 landers, and those data are re-examined closely, finding power-law amplitude characteristics and substantial differences between the different profiles. It is concluded that some kind of frequent electrical activity is supported by the preponderance of observations, but optical emissions are not consistent with terrestrial levels of activity. Venus' activity may, like Earth's, have strong temporal and/or spatial variability, which coupled with the relatively short accumulated observation time for optical measurements, can lead to qualitative discrepancies between observation reports. We note a number of previously unconsidered observations and outline some considerations for future observations.

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Lightning Locators

Shirer¹,

Roeder²,

Shirer³

et al. 2002

Encyclopedia of Imaging Science and Technology

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Locating lightning in real time is an old problem. Radio techniques developed in the early to mid‐twentieth century used crossed‐loop cathode‐ray direction finders (CRDF) that provide the bearing but not the range to the lightning source. Direction‐finding (DF) systems typically sense the radio signal, known as atmospherics , spherics , or ‘ sferics , that is emitted by lightning and that most listeners of AM radios interpret as interference, static , or radio noise . Quite generally, lightning radiates electromagnetic pulses that span an enormous range of frequencies. In this article, the radio signal refers to the portion of the electromagnetic spectrum that covers frequencies less than 3 × 10 8 kilohertz (denoted kHz), or 300 GHz, and the optical signal refers to frequencies greater than 3 × 10 8 kHz. Also, when not qualified here, electromagnetic radiation refers to the radio signal. Lightning sensing systems have important applications in meteorology. Certainly, these systems can help to detect and forecast the arrival of thunderstorms by monitoring their positions, motions, and intensities. Such systems are also important for lightning safety and for protecting natural resources in a diverse set of real‐time applications, including fire and personnel safety, aircraft routing, missile launch decisions, power grid operation, and weather forecasting. Lightning is a significant threat to people but far too often is underrated. Lightning sensing systems, especially those that detect intracloud lightning, are being investigated as tools for predicting severe thunderstorms, including tornadoes, microbursts, and hail. Lightning data are also being investigated as possible input for small‐scale numerical weather forecast models to supplement the usual observations of pressure, temperature, humidity, and winds. This article is not an exhaustive survey of all real‐time and research lightning location systems, but it provides a comprehensive overview of the topic. It is split into two major parts; the first reviews the many important concepts and defines the terminology used to describe them, and the second covers the different major types of operational lightning location systems by describing an example of each in detail. Many of the lightning facts herein are documented thoroughly in the references. The methods and detection systems reviewed in this article are also described on various World Wide Web (www) sites. The addresses for many of these sites are given.

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FORTE observations of simultaneous VHF and optical emissions from lightning: Basic phenomenology

Cited by 80 publications

References 30 publications

Revisiting "Narrow Bipolar Event" intracloud lightning using the FORTE satellite

Revisiting "Narrow Bipolar Event" intracloud lightning using the FORTE satellite

Lightning detection on Venus: a critical review

Lightning Locators

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FORTE observations of simultaneous VHF and optical emissions from lightning: Basic phenomenology

Cited by 80 publications

References 30 publications

Revisiting &quot;Narrow Bipolar Event&quot; intracloud lightning using the FORTE satellite

Revisiting &quot;Narrow Bipolar Event&quot; intracloud lightning using the FORTE satellite

Lightning detection on Venus: a critical review

Lightning Locators

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Revisiting "Narrow Bipolar Event" intracloud lightning using the FORTE satellite

Revisiting "Narrow Bipolar Event" intracloud lightning using the FORTE satellite