电子激发高空大气辐射模拟装置的研制及初步应用

doi:10.3969/j.issn.1007-5461.2024.02.004

量子电子学报 ›› 2024, Vol. 41 ›› Issue (2): 215-225.doi: 10.3969/j.issn.1007-5461.2024.02.004

电子激发高空大气辐射模拟装置的研制及初步应用

何睿祺 1,2, 刘向农 1, 温作赢 2, 顾学军 2, 张为俊 2, 戴聪明 2*, 李建玉 2, 唐小锋 2

( 1 合肥工业大学汽车与交通工程学院, 安徽合肥 230009; 2 中国科学院合肥物质科学研究院安徽光学精密机械研究所, 安徽合肥 230031 )

收稿日期:2022-08-30 修回日期:2022-10-12 出版日期:2024-03-28 发布日期:2024-03-28
通讯作者: E-mail: cmdai@aiofm.ac.cn E-mail:E-mail: cmdai@aiofm.ac.cn
作者简介:何睿祺 ( 1997 - ), 河南洛阳人, 研究生, 主要从事电子激发光谱方面的研究。E-mail:hrq_edu@qq.com
基金资助:
国家自然科学基金 (42120104007, 91961123), 中国科学院合肥大科学中心重点研发项目 (2020HSCKPRD001)

Development and preliminary application of electron⁃excited upper atmosphere radiation simulating setup

HE Ruiqi 1,2, LIU Xiangnong 1, WEN Zuoying 2, GU Xuejun 2, ZHANG Weijun 2, DAI Congming 2*, LI Jianyu 2, TANG Xiaofeng 2

( 1 School of Automotive and Transportation Engineering, Hefei University of Technology, Hefei 230009, China; 2 Anhui Institute of Optics and Fine Mechanics, HFIPS, Chinese Academy of Sciences, Hefei 230031, China )

Received:2022-08-30 Revised:2022-10-12 Published:2024-03-28 Online:2024-03-28

摘要/Abstract

摘要： 地球大气组分与高能电子之间的电荷交换和能量传递在极光和气辉等高空大气发光现象中扮演着重要角色。通过搭建基于真空系统的电子激发高空大气辐射地面模拟装置, 验证了高能电子对高空中性大气的电离激发及其辐射跃迁机制。该装置可实现从102 Pa 过渡到10-3 Pa 超过5 个量级的真空梯度、 102～103 eV 能量范围内的电子加速聚焦以及近紫外-可见光-近红外波段的宽光谱测量。将该模拟装置初步应用于N2和O2的电子激发实验, 比较了大气中两种主要成分的谱线分布特征, 发现激发光谱强度与电子能量成正相关, 且在相同条件下N2的激发光谱强度远大于O2。利用单组分气体的已知光谱带系标定了实际大气的电子激发光谱, 结果表明实际大气与纯N2的激发光谱分布趋于一致但强度有所下降。初步测试与应用表明该装置可用于模拟高能电子沉降过程中与中高层大气组分的碰撞激发反应。

关键词: 光谱学, 电离光谱, 电子激发, 大气辐射, 高空大气

Abstract: The charge exchange and the energy transfer between Earth's upper atmosphere and highenergy electrons play an important role in the upper atmospheric luminous phenomena such as aurora and airglow. By building a ground-based simulating setup for electron excited high-altitude atmospheric radiation based on a vacuum system, the ionizing excitation of neutral molecules induced by electron impact and the corresponding radiative transition mechanism in the upper atmosphere are verified here. The device can create a vacuum gradients of more than 5 orders from 102 to 10-3 Pa, generate electrons with kinetic energy in 102-103 eV and monitor spectral transitions with wide range from near ultraviolet to near infrared. As an illustrated example, the setup has been applied to study the electron excitation of N2 and O2, the two main components of atmosphere, and their spectral distributions are measured and compared. It's found that the emission spectral intensity of N2 is not only positively correlated with electron energy, but also much higher than that of O2 under the same condition. Using the known spectral bands of the pure gases of N2 and O2, the excited spectrum of the actual atmosphere has been assigned, which shows that the emission bands of the air and pure N2 tend to be convergent, but the former's intensity decreases in some contents. These results demonstrate that the developed setup can be used to simulate the colliding excitation of middle and upper atmosphere components during the deposition of high-energy electrons.

Key words: spectroscopy, ionization spectrum, electron excitation, atmospheric radiation, upper atmosphere

中图分类号:

O561.3

何睿祺 , 刘向农 , 温作赢 , 顾学军 , 张为俊 , 戴聪明 , 李建玉 , 唐小锋 . 电子激发高空大气辐射模拟装置的研制及初步应用[J]. 量子电子学报, 2024, 41(2): 215-225.

HE Ruiqi , LIU Xiangnong , WEN Zuoying , GU Xuejun , ZHANG Weijun , DAI Congming , LI Jianyu , TANG Xiaofeng . Development and preliminary application of electron⁃excited upper atmosphere radiation simulating setup[J]. Chinese Journal of Quantum Electronics, 2024, 41(2): 215-225.

参考文献

[1] Lu D R, Chen Z Y, Guo X, et al. Recent progress in near space atmospheric environment study[J]. Advances in Mechanics, 2009, 39(06): 674-682(in Chinese).
吕达仁，陈泽宇，郭霞，等. 临近空间大气环境研究现状[J]. 力学进展, 2009, 39(06): 674-682.
[2] Schunk R, Nagy A. Ionospheres: physics, plasma physics, and chemistry[M]. 2. Cambridge: Cambridge University Press, 2009: 22-31.
[3] Feldman P D, Doering J P. Auroral electrons and the optical emissions of nitrogen[J]. Journal of Geophysical Research, 1975, 80(19): 2808-2812.
[4] Chakrabarti S. Ground based spectroscopic studies of sunlit airglow and aurora[J]. Journal of atmospheric and solar-terrestrial physics, 1998, 60(14): 1403-1423.
[5] Dothe H, Duff J, Gruninger J, et al. Auroral radiance modeling with SAMM2[C]. Remote Sensing of Clouds and the Atmosphere XIV, 2009: 67-73.
[6] Heavner M, Morrill J, Siefring C, et al. Near-ultraviolet and blue spectral observations of sprites in the 320-460 nm region: N2(2PG) emissions[J]. Journal of Geophysical Research: Space Physics, 2010, 115(A7).
[7] Kuo C, Su H, Hsu R. The blue luminous events observed by ISUAL payload on board FORMOSAT-2 satellite[J]. Journal of Geophysical Research: Space Physics, 2015, 120(11): 9795-9804.
[8] Stenbaek‐Nielsen H, Mcharg M, Haaland R, et al. Optical spectra of small-scale sprite features observed at 10,000 fps[J]. Journal of Geophysical Research: Atmospheres, 2020, 125(20): e2020JD033170.
[9] Krupenie P H. The spectrum of molecular oxygen[J]. Journal of Physical and Chemical Reference Data, 1972, 1(2): 423-534.
[10] Lofthus A, Krupenie P H. The spectrum of molecular nitrogen[J]. Journal of Physical and Chemical Reference Data, 1977, 6(1): 113-307.
[11] Borst W L, Zipf E C. Cross section for electron-impact excitation of the (0,0) first negative band of N2+ from threshold to 3 keV[J]. Physical Review A, 1970, 1(3): 834-840.
[12] Srivastava B N. Emission cross section for the first negative band system of oxygen produced by electron impact[J]. Journal of Quantitative Spectroscopy and Radiative Transfer, 1970, 10(11): 1211-1217.
[13] Finn T G, Aarts J F M, Doering J P. High energy-resolution studies of electron impact optical excitation functions I. The second positive system of N2[J]. The Journal of Chemical Physics, 1972, 56(11): 5632-5636.
[14] Schulman M B, Sharpton F A, Chung S, et al. Emission from oxygen atoms produced by electron-impact dissociative excitation of oxygen molecules[J]. Physical Review A, 1985, 32(4): 2100-2116.
[15] Van Zyl B, Pendleton Jr. W. N2+(X), N2+(A), and N2+(B) production in e? + N2 collisions[J]. Journal of Geophysical Research: Space Physics, 1995, 100(A12): 23755-23762.
[16] Itikawa Y. Cross sections for electron collisions with nitrogen molecules[J]. Journal of Physical and Chemical Reference Data, 2006, 35(1): 31-53.
[17] Meng X, Wu B, Gao X-F, et al. Vibrationally resolved photoemissions of N2 (C3Πu → B3Πg) and CO (b3Σ+ → a3Π) by low-energy electron impacts[J]. The Journal of Chemical Physics, 2020, 153(2): 024301.
[18] Feuerstein B, Grum-Grzhimailo A N, Mehlhorn W. Electron impact excitation cross sections of sodium autoionizing state from threshold to 1.5 keV[J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 1998, 31(3): 593-608.
[19] Geng D-P, Yang Y-G, Liu S-H, et al. Design of an efficient monochromatic electron source for inverse photoemission spectroscopy[J]. Chinese Physics C, 2014, 38(11): 118202.
[20] Mangina R S, Ajello J M, West R A, et al. High-resolution electron-impact emission spectra and vibrational emission cross sections from 330-1100 nm for N2[J]. The Astrophysical Journal Supplement Series, 2011, 196(1): 13.
[21] ?imek M. Optical diagnostics of streamer discharges in atmospheric gases[J]. Journal of Physics D: Applied Physics, 2014, 47(46): 463001.
[22] Terrell C A, Hansen D L, Ajello J M. The near-ultraviolet and visible emission spectrum of O2 by electron impact[J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 2004, 37(9): 1931-1949.
[23] Christensen A B, Rees M H, Romick G J, et al. O I (7774 ?) and O I (8446 ?) emissions in aurora[J]. Journal of Geophysical Research: Space Physics, 1978, 83(A4): 1421-1425.
[24] Oyama S-I, Tsuda T T, Hosokawa K, et al. Auroral molecular-emission effects on the atomic oxygen line at 777.4 nm[J]. Earth, Planets and Space, 2018, 70(1): 166.

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电子激发高空大气辐射模拟装置的研制及初步应用

Development and preliminary application of electron⁃excited upper atmosphere radiation simulating setup

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