Spectroscopic diagnostics of laboratory air plasmas as a benchmark for spectral rotational (gas) temperature determination in TLEs

Parra-Rojas, F. C.; Passas, María; Carrasco, Esther; Luque, Alejandro; Tanarro, Isabel; Šimek, Milan; Gordillo‐Vázquez, F. J.

doi:10.1002/jgra.50433

Cited by 29 publications

(21 citation statements)

References 53 publications

(145 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This spectrograph has a mean spectral resolution of 0.24 nm (with a linear dispersion of 0.07 nm/pixel) and covers the wavelength range between 700 nm and 800 nm with 40 ms (25 fps) temporal resolution (Passas, Sánchez, et al, ) (see supporting information for details). GRASSP is in operation for ground‐based systematic imaging and spectroscopic surveys of all sorts of TLEs in Europe since October 2012 when the first GRASSP version (Parra‐Rojas, Passas, et al, ) was deployed in the Calar Alto Astronomical Observatory (CAHA) (3713'23''N 232'45''W) placed 2,168 m above sea level in southeast Spain. GRASSP recorded from Calar Alto Astronomical Observatory many images of distant TLEs (Passas et al, ) and carried out meteor spectroscopy (Passas, Madiedo, & Gordillo‐Vazquez , ).…”

Section: Introductionmentioning

confidence: 99%

High Spectral Resolution Spectroscopy of Sprites: A Natural Probe of the Mesosphere

et al. 2018

Self Cite

View full text Add to dashboard Cite

We present the first high spectral resolution (0.24 nm) spectra of sprites. These spectra were recorded in Europe in the summers and falls of 2015 and 2016 and during January 2017. The use of high spectral resolution has allowed us to resolve for the first time the internal (vibrorotational) structure of the sprite molecular N2 first positive system and to quantify the local gas (rotational) temperature of the mesosphere under the influence of sprites revealing that there is no measurable heating of the atmosphere associated to sprites at the altitudes explored. The temperatures of the explored region of the mesosphere range between 149 K ± 10 K and 226 K ± 20 K. The recorded spectroscopic data also provide valuable quantitative information on the concentrations of some of the vibrational levels of molecular nitrogen involved in transient red‐near‐infrared optical emissions from sprites. The regions of the transient luminous events recorded with our spectrograph (equipped with a horizontally oriented slit) correspond to altitudes in the 66 km to 74 km ± 5 km range.

show abstract

Section: Introductionmentioning

confidence: 99%

High Spectral Resolution Spectroscopy of Sprites: A Natural Probe of the Mesosphere

et al. 2018

Self Cite

View full text Add to dashboard Cite

show abstract

“…The chemical impact and optical signatures of TLEs have been widely investigated by several authors (Gordillo‐Vázquez, ; Kuo et al, ; Parra‐Rojas, Luque, & Gordillo‐Vázquez, ; ; Sentman et al, ; Winkler & Notholt, ). There have also been some ground‐, balloon‐, plane‐, and space‐based instrumentation devoted to the study of TLEs, such as the Imager of Sprites and Upper Atmospheric Lightning (ISUAL; Chern et al, ; Hsu et al, ) of the National Space Organization, Taiwan, that was in operation between May 2004 and June 2016, the Global LIghtning and sprite MeasurementS (GLIMS; Adachi et al, ; Sato et al, ) of the Japan Aerospace Exploration Agency between 2012 and 2015, and the GRAnada Sprite Spectrograph and Polarimeter (Gordillo‐Vázquez et al, ; Parra‐Rojas, Passas, et al, ; Passas et al, , ) and the high‐speed ground‐based photometer array known as PIPER (Marshall et al, ), both of them currently in operation. Despite the valuable advance in the knowledge of TLEs in the last decades, there are still several open questions about the inception and evolution of these events or their global chemical influence in the atmosphere.…”

Section: Introductionmentioning

confidence: 99%

Spectroscopic Diagnostic of Halos and Elves Detected From Space‐Based Photometers

et al. 2018

Self Cite

View full text Add to dashboard Cite

In this work, we develop two spectroscopic diagnostic methods to derive the peak reduced electric field in transient luminous events (TLEs) from their optical signals. These methods could be used to analyze the optical signature of TLEs reported by spacecraft such as Atmosphere‐Space Interactions Monitor (European Space Agency) and the future Tool for the Analysis of RAdiations from lightNIngs and Sprites (Centre National d'Études Spatiales). As a first validation of these methods, we apply them to the predicted (synthetic) optical signatures of halos and elves, two types of TLEs, obtained from electrodynamical models. This procedure allows us to compare the inferred value of the peak reduced electric field with the value computed by halo and elve models. Afterward, we apply both methods to the analysis of optical signatures of elves and halos reported by Global LIghtning and sprite MeasurementS (Japan Aerospace Exploration Agency) and Imager of Sprites and Upper Atmospheric Lightning (National Space Organization) spacecraft, respectively. We conclude that the best emission ratios to estimate the maximum reduced electric field in halos and elves are the ratio of the second positive system of N2 to first negative system (FNS) of N 2+, the first positive system of N2 to FNS of N 2+ and the Lyman‐Birge‐Hopfield band of N2 to FNS of N 2+. In the case of reduced electric fields below 150 Td, we found that the ratio of the second positive system of N2 to first positive system of N2 can also be used to reasonably estimate the value of the field. Finally, we show that the reported optical signals from elves can be treated following an inversion method in order to estimate some of the characteristics of the parent lightning.

show abstract

“…More recently, 1-ms time resolution spectrograph observations were achieved (Stenbaek-Nielse and McHarg 2004). The altitude-resolved spectrum (with a 3-ms temporal resolution and approximately 3-nm spectral resolution, from 640 -820 nm) revealed that the upper vibrational state population of the N 2 1P bands, B 3 Π g , varies with the altitude, which is similar to the laboratory afterglow at low pressure (Kanmae et al 2007(Kanmae et al , 2010Parra-Rojas et al 2013;Stenbaek-Nielsen et al 2013).…”

Section: Introductionmentioning

confidence: 66%

Recent work on sprite spectrum in Taiwan

Chen

Kuo

et al. 2017

Terr. Atmos. Ocean. Sci.

View full text Add to dashboard Cite

This paper reports on the recent developments in spectroimagers for sprite campaigns in Taiwan. We first introduce two types of spectroimagers, the slit and slitless types, and discuss their advantages and shortcomings. Next we explore the instrument development and procedures undertaken for this study. In 2006, a slit spectroimager was installed for a sprite campaign and on 15 August of that year, two sprite spectra were recorded using the slit spectroimager along with seven sprites, one halo, one ELVES emission and two jets. By the end of 2015, a slitless spectroimager had been successfully constructed and was ready to conduct additional investigations. On 7 May 2016, a sprite spectrum was recorded using the slitless spectroimager. Following an examination of the calibrations (comprising detection region field of view, wavelength calibration, and response curve), data analysis, and additional calibrations (comprising elevation and azimuthal angles, atmospheric transmittance, and theoretical wavelength calculations) performed in this study, we present the results from our observed sprite spectra using the slit and slitless spectroimagers.

show abstract

Spectroscopic diagnostics of laboratory air plasmas as a benchmark for spectral rotational (gas) temperature determination in TLEs

Cited by 29 publications

References 53 publications

High Spectral Resolution Spectroscopy of Sprites: A Natural Probe of the Mesosphere

High Spectral Resolution Spectroscopy of Sprites: A Natural Probe of the Mesosphere

Spectroscopic Diagnostic of Halos and Elves Detected From Space‐Based Photometers

Recent work on sprite spectrum in Taiwan

Contact Info

Product

Resources

About