Metastable Helium Lidar for Thermosphere and Lower Exosphere Measurements: Instrument Description and Initial Results

Zhao, Ruocan; Liu, Zhenwei; Xue, Xianghui; Zhou, Hang; Wang, Zhaofeng; Liu, Yingyu; Li, Jiangtao; Sun, Dongsong; Lan, Jiaxin; Chen, Tingdi; Zhao, Dongfeng; Dou, Xiankang

doi:10.1029/2024sw003977

Space Weather

2024

DOI: 10.1029/2024sw003977

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Metastable Helium Lidar for Thermosphere and Lower Exosphere Measurements: Instrument Description and Initial Results

Ruocan Zhao,

Zhenwei Liu,

Xianghui Xue

et al.

Abstract: In this work, we present a metastable helium lidar system for the measurements of metastable helium He(23S) density in the thermosphere and lower exosphere. This lidar system consists of a high power 1,083 nm pulsed laser, a 1 m aperture laser beam expander, six 1 m aperture receiving telescopes and a superconducting nanowire single‐photon detector (SNSPD). This system realizes metastable helium density detection up to 1,000 km. Daily rapid variation of metastable helium density within several hours was measur… Show more

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Seasonal and Altitude Dependence of Thermospheric Metastable Helium Densities Measured by Fluorescence Lidar

Geach,

Kaifler

2024

Geophysical Research Letters

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Airglow originating from metastable helium He(S) at 1,083 nm has been used to study the upper thermosphere since its discovery in 1959, yielding insights into, for example, solar EUV intensities and thermospheric photoelectron densities. For over 6 decades, these measurements were made passively, relying on solar illumination of the He(S) layer to produce a detectable signal, resulting in a column integration of the He(S) layer. Recently, the first height‐resolved measurements of He(S) density were made by fluorescence lidar, opening a new window for studying the upper thermosphere. We report on a series of 51 measurements by this instrument spanning an entire winter season and extending to an altitude of 1,000 km, revealing a broad He(S) layer that peaks at higher altitudes than previously expected.

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Seasonal and Altitude Dependence of Thermospheric Metastable Helium Densities Measured by Fluorescence Lidar

Geach,

Kaifler

2024

Geophysical Research Letters

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Metastable Helium Lidar for Thermosphere and Lower Exosphere Measurements: Instrument Description and Initial Results

Cited by 1 publication

References 32 publications

Seasonal and Altitude Dependence of Thermospheric Metastable Helium Densities Measured by Fluorescence Lidar

Seasonal and Altitude Dependence of Thermospheric Metastable Helium Densities Measured by Fluorescence Lidar

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