Surface charging effect of the satellite SMILE

Xu Liang-Liang; Cai Ming-Hui; Yang Tao; Han Jian-Wei

doi:10.7498/aps.69.20200044

Abstract

When the satellite is on orbit, the surrounding plasma environment will interact with the spacecraft surface, accumulate charges on the spacecraft surface and cause surface charging effect, which could lead to electrostatic discharge and affect the running of the spacecraft. SMILE is a satellite operating in a solar synchronous and high inclination large elliptical orbit. The on-orbit motion will encounter ionospheric plasma, magnetospheric plasma and solar wind plasma, pass through the region of the outer radiation belt enriched by high-energy electrons. These environmental factors can cause the surface charging effect on satellite and affect on-orbit security of the satellite and the acquisition of scientific data. Utilizing the software simulation of spacecraft plasma interaction system, the charging effects of SMILE satellite surface in solar wind plasma, magnetic tail plasma and extremely harsh plasma environment have been simulated, and the charging potential distribution on its surface have been obtained. The results show that the surface charging potential varies in different environments, but all comfort with the design requirements. The analysis of surface current shows that the secondary electron emission has great influence on surface charging in various plasma environments. Under sun illumination, photoelectron emission dominates surface charging. By analyzing the charge current on the surface on the eclipse, the calculated results can supply the experimental curve of the secondary electron emission coefficient of indium tin oxide materials.

Keywords:

Authors and contacts

1.
National Space Science Center, Chinese Academy of Sciences, Beijing 100190, China
2.
University of Chinese Academy of Sciences, Beijing 100049, China

Corresponding author: Cai Ming-Hui, caiminghui@nssc.ac.cn

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References

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Cited By

图 1 SMILE卫星模型图. 红绿蓝三个轴分别为x, y, z方向

Figure 1. The model of SMILE. The red, green and blue axes are in the x, y, z direction, respectively.

DownLoad: Full-Size Img PowerPoint

图 2 阴影区节点4的平均表面电位　(a) 磁尾瓣等离子体环境; (b) 太阳风等离子体环境; (c) GEO极端恶劣等离子体环境

Figure 2. Average surface potential on node 4 on the eclipse: (a) The magnetic tail lobes plasma; (b) the solar wind plasma; (c) the GEO worst case plasma.

DownLoad: Full-Size Img PowerPoint

图 3 阴影区节点4的表面电流　(a) 磁尾瓣等离子体环境; (b) 太阳风等离子体环境; (c) GEO极端恶劣等离子体环境

Figure 3. Surface current on node 4 on the eclipse; (a) The magnetic tail lobes plasma; (b) the solar wind plasma; (c) the GEO worst case plasma.

DownLoad: Full-Size Img PowerPoint

图 4 光照下节点4的平均表面电位　(a) 磁尾瓣等离子体环境; (a) 太阳风等离子体环境; (c) GEO极端恶劣等离子体环境

Figure 4. Average surface potential on node 4 under sun illumination: (a) The magnetic tail lobes plasma; (b) the solar wind plasma; (c) the GEO worst case plasma.

DownLoad: Full-Size Img PowerPoint

图 5 光照下节点4的表面电流　(a) 磁尾瓣等离子体环境; (b) 太阳风等离子体环境; (c) GEO极端恶劣等离子体环境

Figure 5. Surface current on node 4 under sun illumination: (a) The magnetic tail lobes plasma; (b) the solar wind plasma; (c) the GEO worst case plasma.

DownLoad: Full-Size Img PowerPoint

表 1 SMILE卫星模型电路节点、表面材料及电路设置

Table 1. Design of nodes, surface materials and circuits of SMILE model.

航天器部件	电路节点	表面材料	电路设置/Ω
载荷仓(底面)	0	ITO
载荷仓	1—5	ITO	20000
伸杆天线	6	KAPT	20000
推进器	7—10	ITO	20000
太阳电池下表面	11, 12	CFRP	37500
太阳电池上表面	13, 14	ITO	20000
+X面测控天线顶端	15, 17	PCBZ	20000
+X面测控天线底端	16, 18	ITO	20000
星敏	19—21	ITO	20000
推进舱+X面探测器	22	AL	20000
推进舱-X面探测器	23	AL	20000
散热板对内面	24, 26, 28	ITO	20000
散热板对外面	25, 27, 29	PCBZ	20000
-X面测控天线	30, 31	PCBZ	20000
LIA安装面、测量面	32, 34, 36, 38	AL	20000
LIA对外面	33, 37	PCBZ	20000
LIA靠星体面	35, 39	ITO	20000
探测器镜头	40—42	ITO	20000

DownLoad: CSV

表 2 等离子体环境参数

Table 2. Parameters of various plasma environment.

等离子体环境		离子密度	电子密度	离子温度	电子温度
等离子体环境		cm^–3	cm^–3	eV	eV
磁尾瓣		0.1	0.1	540	180
太阳风		8.7	8.7	12	10
GEO极端恶劣	成分1	0.6	0.2	2000	4000
GEO极端恶劣	成分2	1.3	1.2	28000	27500

DownLoad: CSV

[1]	Ferguson D 1993 31st Aerospace Sciences Meeting Reno, NV, USA, January 11–14, 1993 p705
[2]	王立 1995 真空与低温 1 2 Wang L 1995 Vac. Cryogenics 1 2
[3]	王立, 秦晓刚 2002 真空与低温 8 2 Wang L, Qin X G 2002 Vac. Cryogenics 8 2
[4]	Ch J Mateo-Velez, Sarrail H P, Roussel J F 2010 Technical Manual of SPIS Final Report FR 10/14511 DESP
[5]	Whipple E C, Krinsky I S, Torbert R B, Olsen R C 1983 Spacecraft Plasma Interactions and Their Influence on Field and Particle Measurements, Proceedings of the 17th ESLAB Symposium Noordwijk, The Netherlands, September 13–16, 1983 p35
[6]	Reasoner D L, Lennartsson W, Chappell C R 1976 Spacecraft Charging by Magnetospheric Plasmas 47 89
[7]	庞永江 2001 硕士学位论文 (北京: 中国科学院) Pang Y J 2001 M. S. Thesis (Beijing: Chinese Academy of Sciences) (in Chinese)
[8]	田立成, 石红, 李娟, 张天平 2012 航天器环境工程 29 2 Tian L C, Shi H, Li J, Zhang T P 2012 Spacecraft Environ. Eng. 29 2
[9]	杨昉, 师立勤, 刘四清, 龚建村 2011 空间科学学报 31 4 Yang F, Shi L Q, Liu S Q, Gong J C 2011 Chin. J. Spac. Sci. 31 4
[10]	Schmidt R, Arends H, Pedersen A, Rüdenauer F, Fehringer M, Narheim B T, Svenes R, Kvernsveen K, Tsuruda K, Mukai T, Hayakawa H, Nakamura H M 1995 JGR: Space Physics 100 A9
[11]	Riedler W, Torkar K, Rüdenauer F, Fehringer M, Pedersen A, Schmidt R, Grard J L, Arends H, Narheim B T, Troim J, Torbert R, Olsen R C, Whipple E, Goldstein R, Valavanoglou N, Zhao H 1997 The Cluster and Phoenix Missions 79 271
[12]	Pedersen A, Chapell C R, Knott K, Olsen R C 1983 Spacecraft Plasma Interactions and Their Influence on Field and Particle Measurements, Proceedings of the 17th ESLAB Symposium ESA SP-198 Noordwijk, The Netherlands, September 13–16, 1983 p185
[13]	张国荣, 柯建新, 许滨 2014 计算机仿真 9 38 Google Scholar Zhang G R, Ke J X, Xu B 2014 Comput. Simul. 9 38 Google Scholar
[14]	原青云, 孙永卫 2015 河北师范大学学报: 自然科学版 1 38 Yuan Q Y, Sun Y W 2015 J. Hebei Normal Univ.: Nat. Sci. Ed. 1 38
[15]	杨集, 陈贤祥, 夏善红 2007 微纳电子技术 44 7 Google Scholar Yang J, Chen X X, Xia S H 2007 Micronanoelectronic Technol. 44 7 Google Scholar
[16]	姜春华, 赵正予 2008 航天器环境工程 25 2 Jiang C H, Zhao Z Y 2008 Spacecraft Environ. Eng. 25 2
[17]	顾超超, 陈晓宁, 林楚 2017 微型机与应用 36 11 Gu C C, Chen X N, Lin C 2017 Microcomputer & Its Applications 36 11
[18]	朱基聪, 方美华, 武明志, 田鹏宇, 费涛 2018 真空科学与技术学报 38 6 Zhu J C, Fang M H, Wu M Z, Tian P Y, Fei T 2018 Chin. J. Vac. Technol. 38 6
[19]	Ferro O J, Hess S, Seran E, Denis P 2018 IEEE Trans. Plasma Sci. 46 3 Google Scholar
[20]	Galgani G, Antonelli M, Bandinelli M, Scione E, Scorzafaval E Esa Workshop on Aerospace Emc. IEEE Valencia, Spain, May 23–25, 2016 p89
[21]	陈益峰, 杨生胜, 李得天, 秦晓刚, 王俊, 柳青 2015 原子能科学技术 49 1673 Google Scholar Chen Y F, Yang S S, Li D T, Qin X G, Wang J, Liu Q 2015 Atom. Energ. Sci. Technol. 49 1673 Google Scholar
[22]	Kuznetsova I A, Hessb S L G, Zakharova A V, Ciprianic F, Serand E, Popela S I, Lisine E A, Petrove O F, Dolnikova G G, Lyasha A A, Kopnina K I 2018 Planet. Space Sci. 156 62 Google Scholar
[23]	赵呈选, 李得天, 杨生胜, 秦晓刚, 王俊 2017 高电压技术 43 1438 Zhao C X, Li D T, Yang S S, Qin X G, Wang J 2017 High Voltage Eng. 43 1438
[24]	毕嘉眙, 李磊 2018 空间科学学报 38 909 Google Scholar Bi J Y, Li L 2018 Chin. J. Space Sci. 38 909 Google Scholar
[25]	朱基聪, 方美华, 全荣辉, 田鹏宇, 梁尔涛 2018 南京航空航天大学学报 50 422 Zhu J C, Fang M H, Quan R H, Tian P Y, Liang E T 2018 J. Nanjing Univ. Aeronaut. Astronautics 50 422
[26]	Garrett H B 1981 Rev. Geophys. Space Phys. 19 4
[27]	Smith H M, Langmuir I 1926 Phys. Rev. 28 4
[28]	Bernstein I B, Rabinowitz I 1959 Phys. Fluids 2 2
[29]	Laframboise J G 1966 University of Toronto, Institute for Aerospace Studies, UTIAS Report No. 100
[30]	Chen F F 1965 Plasma Phys. 7 1
[31]	买胜利, 王立, 李凯, 秦晓刚 2006 真空与低温 12 2 Mai S L, Wang L, Li K, Qin X G 2006 Vac. Cryogenics 12 2
[32]	王思展 2019 科技与创新 8 14 Wang S Z 2019 Sci. Technol. Innov. 8 14
[33]	王思展, 黄建国, 姜利祥, 王军伟 2019 环境技术 4 18 Wang S Z, Huang J G, Jiang L X, Wang J W 2019 Environ. Technol. 4 18
[34]	陈益峰, 杨生胜, 李得天, 秦晓刚, 史亮, 冯娜 2014 现代应用物理 5 3 Chen Y F, Yang S S, Li D T, Qin X G, Shi L, Feng N 2014 Mod. Appl. Phys. 5 3
[35]	杨集, 陈贤祥, 周杰, 夏善红 2010 宇航学报 31 531 Google Scholar Yang J, Chen X X, Zhou J, Xia S H 2010 J. Astronautics 31 531 Google Scholar

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