Particle-in-Cell Simulation Study on the Floating Potential of Spacecraft in the Low Earth Orbit 被引量：2

Particle-in-Cell Simulation Study on the Floating Potential of Spacecraft in the Low Earth Orbit

下载PDF

导出

摘要 In order to further understand the characteristics of the floating potential of low earth orbit spacecraft,the effects of the electron current collection area,background electron temperature,photocurrent emission,spacecraft wake,and the shape of spacecraft on spacecraft floating potential were studied here by particle-in-cell simulation in the low earth orbit.The simulation results show that the electron current collection area and background electron temperature impact on the floating potential by changing the electron current collection of spacecraft.By increasing the electron current collection area or background electron temperature,the spacecraft will float at a lower electric potential with respect to the surrounding plasma.However,the spacecraft wake affects the floating potential by increasing the ion current collected by spacecraft.The emission of the photocurrent from the spacecraft surface,which compensates for the electrons collected from background plasma,causes the floating potential to increase.The shape of the spacecraft is also an important factor influencing the floating potential. In order to further understand the characteristics of the floating potential of low earth orbit spacecraft,the effects of the electron current collection area,background electron temperature,photocurrent emission,spacecraft wake,and the shape of spacecraft on spacecraft floating potential were studied here by particle-in-cell simulation in the low earth orbit.The simulation results show that the electron current collection area and background electron temperature impact on the floating potential by changing the electron current collection of spacecraft.By increasing the electron current collection area or background electron temperature,the spacecraft will float at a lower electric potential with respect to the surrounding plasma.However,the spacecraft wake affects the floating potential by increasing the ion current collected by spacecraft.The emission of the photocurrent from the spacecraft surface,which compensates for the electrons collected from background plasma,causes the floating potential to increase.The shape of the spacecraft is also an important factor influencing the floating potential.

作者汤道坦杨生胜郑阔海秦晓刚李得天柳青赵呈选杜杉杉

机构地区 Science and Technology on Vacuum & Cryogenics Technology and Physics Laboratory DFH SATELLITE CO.

出处《Plasma Science and Technology》 SCIE EI CAS CSCD 2015年第4期288-293,共6页 等离子体科学和技术（英文版）

基金 supported by National Natural Science Foundation of China(No.11105063)

关键词 spacecraft floating potential PIC electron current collection area electron temperature photocurrent emission spacecraft wake spacecraft shape spacecraft floating potential PIC electron current collection area electron temperature photocurrent emission spacecraft wake spacecraft shape

分类号 V412.41 [航空宇航科学与技术—航空宇航推进理论与工程]

引文网络
相关文献

参考文献13

1Ferguson D C, Snyder D B, Carruth R. 1990, Findings of the ,loint Workshop oil Evaluation of Impacts of Space Station Freedom Ground Configuration. NASA Lewis Research Center, Cleveland. No. NASA TM- 103717.
2Fergus(m D C. 1993, Interact:ions Between Space- craft and Their Environments. 31st Aerospace Sciences Meeting and Exhibit (Nevada.).
3Ferguson D C, Gardner Barbara. 2002, Modeling In- ternational Space Station (ISS) Floating Potentials. Proc. 39th Aerospace Sciences Meeting and Exhibit (Nevada).
4Ferguson D C. 1991, LEO Space Plasma Interactions, Proc. 10th Space Photovoltaic Research and Technol- ogy Conf. (Cleveland) Carruth M R, Vaughn J Spacecr. Rockets, 30:323.
5Carruth M R, Schneider J T, McCollum M, et al. 2001, ISS and Space Environment Interactions Without Op-erating Plasma Contactor. Proc. 39th Aerospace Sci- ences Meeting and Exhibit (Nevada).
6Forest J, Eliasson L, Hilgers A, et al. 2001, A Nev: Spacecraft Plasma Interactions Simulation Software,I PicUp3D/SPIS. 7th Proc. of the Spacecraft Charging: Technology Conf. (The Netherlands) |.
7Birdsall C K, Langdon A B. 1991, Plasma Physics Via Computer Simulation, Institute of Physics Publishing, Bristol.
8Ferguson D C, Hillard G B. 2003, Low Earth Orbit Spacecraft Charging Design Guidelines (Virginia: TheNASA Scientific and Technical Information Program Office, 212287).
9Minow J I, Parker L N. 2007, Spacecraft charging in low temperature environments. 45th AIAA Aerospace Sciences Meeting and Exhibit (Nevada).
10Bibhas R D, David R C. 1977, Photoelectric charging of partially sunlit dielectric surfaces in space. 1st Proc. of the Spacecraft Charging Technology Conf. (Mas- sachusetts).

同被引文献87

1徐婕,李得天,郭美如,赵光平.静态膨胀法真空标准容积比测量及不确定度评定[J].真空与低温,2008,14(3):145-148. 被引量：6
2李得天,郭美如,冯焱,葛敏,张周焕,王占忠,刘波,杨新民.固定流导法校准真空漏孔方法研究[J].真空与低温,2005,11(4):197-204. 被引量：10
3李得天,郭美如,葛敏,张周焕,王占忠,刘波,杨新民.固定流导法真空漏孔校准装置[J].真空科学与技术学报,2006,26(5):358-362. 被引量：30
4李得天,李正海,郭美如,成永军,张涤新,冯焱.超高/极高真空校准装置的研制[J].真空科学与技术学报,2007,27(2):92-96. 被引量：37
5郭宁,邱家稳,江豪成.分子泵对Xe气抽速的测试[J].真空,2007,44(2):15-17. 被引量：4
6冯焱,张涤新.恒压式正压漏孔校准装置的设计[J].真空科学与技术学报,2007,27(5):442-445. 被引量：11
7李得天,郭美如,邱家稳,李正海,成永军,冯焱,张涤新,赵光平,孙海.分流法超高/极高真空校准装置性能研究[J].真空,2007,44(6):1-6. 被引量：9
8张涤新,赵光平,李得天,郭美如,冯焱,徐婕.静态膨胀法真空标准的发展概况[J].真空,2008,45(4):53-57. 被引量：3
9秦晓刚,贺德衍,王骥.基于Geant4的介质深层充电电场计算[J].物理学报,2009,58(1):684-689. 被引量：25
10李得天,赵光平,郭美如,徐婕.静态膨胀法真空标准校准下限延伸方法研究[J].真空科学与技术学报,2009,29(3):314-317. 被引量：8

引证文献2

1赵呈选,李得天,杨生胜,秦晓刚,王俊.低地球轨道航天器表面充电及其环境影响因素[J].高电压技术,2017,43(5):1438-1444. 被引量：8
2李得天,习振华,王永军,成永军,郭宁,王鹢,秦晓刚,张虎忠,李刚,赵呈选.真空测试计量技术及其航天应用[J].真空科学与技术学报,2021,41(9):795-816. 被引量：7

二级引证文献15

1王永军,赵呈选,李得天,王鹢,张海燕,李存惠,庄建宏,张虎忠.空间尘埃探测进展与发展建议[J].前瞻科技,2022(1):38-50. 被引量：1
2白恩培.适应西部大开发战略的需要切实加强农村基层组织建设[J].党的生活（贵州）,2000(1):5-5.
3刘继奎,张可墨,柳青,王松,王斌,国锋.航天器大功率传输介质深层充放电试验研究[J].高电压技术,2018,44(3):864-869. 被引量：9
4刘尚合,胡小锋,原青云,谢喜宁.航天器充放电效应与防护研究进展[J].高电压技术,2019,45(7):2108-2118. 被引量：31
5许亮亮,蔡明辉,杨涛,韩建伟.SMILE卫星的表面充电效应[J].物理学报,2020,69(16):176-183. 被引量：3
6陈诚,姜映红.基于磁共振耦合的激光射束驱动无线充电装置设计[J].激光杂志,2020,41(9):201-205.
7崔阳,杨勇,张晓峰,黄越,李华旺,曹彩霞,赵笙罡,孟娜.SMILE卫星表面电位特性分析[J].真空科学与技术学报,2021,41(1):22-28. 被引量：4
8李得天,习振华,王永军,成永军,郭宁,王鹢,秦晓刚,张虎忠,李刚,赵呈选.真空测试计量技术及其航天应用[J].真空科学与技术学报,2021,41(9):795-816. 被引量：7
9张建平,胡小锋,刘尚合,魏明.强电磁场辐照环境诱发金属电极静电放电时延规律[J].兵工学报,2021,42(11):2409-2417. 被引量：1
10董建伟.现代测试计量技术与仪器研究分析[J].科学与信息化,2022(15):84-86.

1彭菊,郁华玲,左芬.Nonlocal Andreev reflection with Rashba spin-orbital interaction in a triple-quantum-dot ring[J].Chinese Physics B,2010,19(12):489-494.
2奚大顺,余小平.晶体管(下)[J].电子制作,2010,18(12):58-62.
3XU Ke,TIAN XiaoJun,WU ChengDong,LIU Jian,LI MengXin,DONG ZaiLi.Study on the large-scale assembly and fabrication method for SWCNTs nano device[J].Science China Chemistry,2013,56(3):556-561. 被引量：3
4Yehia A.Abdel-Aziz,Muhammad Shoaib.Attitude dynamics and control of spacecraft using geomagnetic Lorentz force[J].Research in Astronomy and Astrophysics,2015,15(1):127-144.
5廖朝阳.利用永久磁场抑制中子管中的电子电流[J].零陵学院学报,2003,24(5):34-36. 被引量：1
6杨鑫松,芮伟国.一类广义单种群Logistic模型正周期解的存在性和唯一性[J].数学物理学报（A辑）,2009,29(5):1442-1452. 被引量：1
7金斗英.密封式中子管中电子电流形成过程[J].吉林大学自然科学学报,1998(1):40-44. 被引量：7
8王鹏飞.电子电路的调试与故障处理探析[J].通讯世界,2016,22(6):256-256. 被引量：1
9孙利民,卢泽新,吴志美.LEO卫星网络的路由技术[J].计算机学报,2004,27(5):659-667. 被引量：39
10钱锰,廖源,杨明.新型浮动板调制器用触发器的设计与实现[J].现代雷达,2005,27(1):52-54. 被引量：8

Plasma Science and Technology

2015年第4期

浏览历史

内容加载中请稍等...

Particle-in-Cell Simulation Study on the Floating Potential of Spacecraft in the Low Earth Orbit 被引量：2

参考文献13

同被引文献87

引证文献2

二级引证文献15

相关作者

相关机构

相关主题

浏览历史