ACTA AERONAUTICAET ASTRONAUTICA SINICA >
Influence of propellant on radio-frequency discharge modes transition characteristics
Received date: 2025-08-31
Revised date: 2025-09-23
Accepted date: 2025-10-28
Online published: 2025-11-03
Supported by
National Natural Science Foundation of China(52572464)
Radio-frequency plasma thrusters, as a type of electrode-less electric thruster, represent a preferred thruster solution for the long-duration operation of air-breathing electric propulsion systems in very low Earth orbits. However, ambient parameters significantly influence the radio-frequency discharge modes and the transition characteristics, which directly determine the thruster’s operational stability under a wide range of conditions. We employed test diagnostic apparatus such as Langmuir probes and optical emission spectroscopy to measure the variations of plasma density and spectral intensity with radio-frequency power under different working conditions, including propellant type, mixture ratio, and flow rate. The influence of the propellant on the transition characteristics of radio-frequency discharge modes was subsequently analyzed. For argon, the discharge mode transition from capacitively coupled plasma to inductively coupled plasma occurs at 300 W, accompanied by consistent jumps in plasma density and spectral intensity. Due to its higher ionization energy, the required radio-frequency power threshold for discharge mode transition is significantly higher for nitrogen than for oxygen. In nitrogen-oxygen mixtures, an increased oxygen proportion reduces the transition threshold; however, a high oxygen fraction can facilitate the formation of negative ions due to its electronegativity, thereby suppressing the free electron density. The threshold of radio-frequency power for mode transition increases with the increase of gas flow rate, driven by the reduced gas residence time, the heightened electron-neutral collision frequency, and the consequent decline in ionization efficiency. The results provide important test evidence for elucidating the characteristics of radio-frequency plasma discharge mode transitions and for optimizing the operational parameters of radio-frequency plasma thrusters under wide-range conditions.
Yu ZHANG , Tao FANG , Chenwen WANG , Peng ZHENG , Jianjun WU , Yuxuan ZHONG . Influence of propellant on radio-frequency discharge modes transition characteristics[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2026 , 47(8) : 132732 -132732 . DOI: 10.7527/S1000-6893.2025.32732
| [1] | 靳旭红, 黄飞, 张俊, 等. 上层大气层飞行器研究进展及气动技术挑战[J]. 航空学报, 2024, 45(22): 030254. |
| JIN X H, HUANG F, ZHANG J, et al. Spacecraft in upper atmosphere: Research development and aerodynamic challenges[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(22): 030254 (in Chinese). | |
| [2] | 郑鹏, 吴建军, 张宇, 等. 用于吸气式电推进系统的射频等离子体推力器实验测试[J]. 航空学报, 2024, 45(21): 130144. |
| ZHENG P, WU J J, ZHANG Y, et al. Experimental testing of inductively coupled radiofrequency plasma thruster for atmosphere-breathing electric propulsion system[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(21): 130144 (in Chinese). | |
| [3] | HERDRICH G, PAPAVRAMIDIS K, MAIER P, et al. Platform and system design study of a VLEO satellite platform using the IRS RF helicon-based plasma thruster[C]∥ 73rd International Astronautical Congress, 2022. |
| [4] | ANDREESCU A T, CRUNTEANU D E, TEODORESCU M V, et al. Development and testing of a helicon plasma thruster based on a magnetically enhanced inductively coupled plasma reactor operating in a multi-mode regime[J]. Applied Sciences, 2024, 14(18): 8308. |
| [5] | ZHENG P, WU J J, ZHANG Y, et al. A comprehensive review of atmosphere-breathing electric propulsion systems[J]. International Journal of Aerospace Engineering, 2020, 2020(1): 8811847. |
| [6] | 孙安邦, 冯晨曦, 张思远, 等. 超低轨道吸气式电推进技术研究进展与展望[J]. 航天器环境工程, 2025, 42(3): 239-255. |
| SUN A B, FENG C X, ZHANG S Y, et al. Research progress and prospects of VLEO air-breathing electric propulsion[J]. Spacecraft Environment Engineering, 2025, 42(3): 239-255 (in Chinese). | |
| [7] | OBRUSNíK A, BíLEK P, HODER T, et al. Electric field determination in air plasmas from intensity ratio of nitrogen spectral bands: I. Sensitivity analysis and uncertainty quantification of dominant processes[J]. Plasma Sources Science and Technology, 2018, 27(8): 085013. |
| [8] | ANDREUSSI T, CIFALI G, GIANNETTI V, et al. Development and experimental validation of a hall effect thruster ram-ep concept[C]∥ 35th International Electric Propulsion Conference, 2017. |
| [9] | SOUHAIR N, MAGAROTTO M, ANDRIULLI R, et al. Prediction of the propulsive performance of an atmosphere-breathing electric propulsion system on cathode-less plasma thruster[J]. Aerospace, 2023, 10(2): 100. |
| [10] | 任琼英, 葛丽丽, 郑慧奇, 等. 超低轨吸气式螺旋波电推进概念研究[J]. 航天器环境工程, 2020, 37(1): 17-24. |
| REN Q Y, GE L L, ZHENG H Q, et al. The concept study of air-breathing helicon thruster used in ultra-low orbit flight[J]. Spacecraft Environment Engineering, 2020, 37(1): 17-24 (in Chinese). | |
| [11] | 李永平, 朱光武, 郑晓亮, 等. 超低轨道热层大气密度原位探测[J]. 北京航空航天大学学报, 2022, 48(10): 1875-1882. |
| LI Y P, ZHU G W, ZHENG X L, et al. In-situ measurement of atmospheric density in very low Earth orbits[J]. Journal of Beijing University of Aeronautics and Astronautics, 2022, 48(10): 1875-1882 (in Chinese). | |
| [12] | HRUBY V, HOHMAN K, SZABO J. Air breathing hall effect thruster design studies and experiments[C]∥ 37th International Electric Propulsion Conference, 2022. |
| [13] | SHABSHELOWITZ A. Study of RF plasma technology applied to air-breathing electric propulsion[D]. Ann Arbor: University of Michigan, 2013: 78-83. |
| [14] | 姜巍. 射频容性耦合等离子体的两维隐格式PIC/MC模拟[D]. 大连: 大连理工大学, 2010: 34-45. |
| JIANG W. Two-dimensional implicit pic/mc simulations for radio-frequency capacitively coupled plasmas[D]. Dalian: Dalian University of Technology, 2010: 34-45 (in Chinese). | |
| [15] | ZHONG Y X, ZHANG Y, WU J J, et al. Optical detection method of discharge mode transition of inductively coupled plasma in an atmosphere-breathing electric propulsion system[J]. Chinese Journal of Aeronautics, 2024, 37(10): 172-183. |
| [16] | TAKAO Y, ONO K. A miniature electrothermal thruster using microwave-excited plasmas: A numerical design consideration[J]. Plasma Sources Science and Technology, 2006, 15(2): 211-227. |
| [17] | SHINOHARA S. High-density helicon plasma science: From basics to applications[M]. Singapore: Springer Singapore, 2022: 170-189. |
| [18] | ELLINGBOE A R, BOSWELL R W. Capacitive, inductive and helicon-wave modes of operation of a helicon plasma source[J]. Physics of Plasmas, 1996, 3(7): 2797-2804. |
| [19] | CANESES J F, BLACKWELL B D. Collisional damping of helicon waves in a high density hydrogen linear plasma device[J]. Plasma Sources Science and Technology, 2016, 25(5): 055027. |
| [20] | ROMANO F, CHAN Y A, HERDRICH G, et al. RF helicon-based plasma thruster (IPT): Design, set-up, and first ignition[C]∥ Space Propulsion Symposium, 2021. |
| [21] | ROMANO F, CHAN Y A, HERDRICH G, et al. RF helicon-based inductive plasma thruster (IPT) design for an atmosphere-breathing electric propulsion system (ABEP)[J]. Acta Astronautica, 2020, 176: 476-483. |
| [22] | MASILLO S, ROMANO F, SOGLIA R, et al. Analysis of electrodeless plasma source enhancement by an externally applied magnetic field for an inductive plasma thruster (IPT)[C]∥ 7th Russian-German Conference on Electric Propulsion, 2018. |
| [23] | ROMANO F, HERDRICH G, CHAN Y A, et al. Design of an intake and a thruster for an atmosphere-breathing electric propulsion system[J]. CEAS Space Journal, 2022, 14(4): 707-715. |
| [24] | HERDRICH G, SKALDEN J, BEHNKE A, et al. An overview of recent thrust balance developments at the institute of space systems[C]∥ 37th International Electric Propulsion Conference, 2022. |
| [25] | ANTIPOV S N, SARGSYAN M A, GADZHIEV M K. Emission spectrum analysis of an atmospheric electrode microwave discharge in argon flow and of a cold plasma jet on its base[J]. Journal of Physics: Conference Series, 2020, 1698(1): 012029. |
| [26] | CHEN F F. Langmuir probes in RF plasma: Surprising validity of OML theory[J]. Plasma Sources Science and Technology, 2009, 18(3): 035012. |
| [27] | CHEN F F. Langmuir probe measurements in the intense RF field of a helicon discharge[J]. Plasma Sources Science and Technology, 2012, 21(5): 055013. |
| [28] | 张天亮. 螺旋波等离子体的模式转换和粒子动理学特性[D]. 北京: 北京理工大学, 2024: 27-40. |
| ZHANG T L. Characteristics of mode transition and species kinetics in helicon plasmas[D]. Beijing: Beijing Institute of Technology, 2024: 27-40 (in Chinese). | |
| [29] | ZHU X M, PU Y K. A simple collisional-radiative model for low-pressure argon discharges[J]. Journal of Physics D: Applied Physics, 2007, 40(8): 2533-2538. |
| [30] | CZERWIEC T, GRAVES D B. Mode transitions in low pressure rare gas cylindrical ICP discharge studied by optical emission spectroscopy[J]. Journal of Physics D Applied Physics, 2004, 37(20): 2827-2840. |
| [31] | CZERWIEC T, GREER F, GRAVES D B. Nitrogen dissociation in a low pressure cylindrical ICP discharge studied by actinometry and mass spectrometry[J]. Journal of Physics D Applied Physics, 2005, 38(24): 4278-4289. |
| [32] | LOEWENHARDT P K, BLACKWELL B D, BOSWELL R W, et al. Plasma production in a toroidal heliac by helicon waves[J]. Physical Review Letters, 1991, 67(20): 2792-2794. |
| [33] | CHEN F F, BLACKWELL D D. Upper limit to landau damping in helicon discharges[J]. Physical Review Letters, 1999, 82(13): 2677-2680. |
| [34] | MOLVIK A W, ELLINGBOE A R, ROGNLIEN T D. Hot-electron production and wave structure in a helicon plasma source[J]. Physical Review Letters, 1997, 79(2): 233-236. |
| [35] | CHEN F F, BOSWELL R W. Helicons-the past decade[J]. IEEE Transactions on Plasma Science, 1997, 25(6): 1245-1257. |
| [36] | 崔瑞林. 氩气螺旋波等离子体的放电特性及波耦合机理[D]. 北京: 北京理工大学, 2022: 18-29. |
| CUI R L. Discharge characteristics and wave coupling mechanism of argon helicon plasma[D]. Beijing: Beijing Institute of Technology, 2022: 18-29 (in Chinese). | |
| [37] | DING Z F, YUAN G Y, GAO W, et al. Effects of impedance matching network on the discharge mode transitions in a radio-frequency inductively coupled plasma[J]. Physics of Plasmas,2008, 15(6): 063506. |
| [38] | BLACKWELL D D, CHEN F F. Two-dimensional imaging of a helicon discharge[J]. Plasma Sources Science and Technology, 1997, 6(4): 569-576. |
| [39] | ZHAO G, WANG H H, SI X L, et al. The discharge characteristics in nitrogen helicon plasma[J]. Physics of Plasmas, 2017, 24(12): 123507. |
| [40] | EOM G S, BAE I D, CHO G, et al. Helicon plasma generation at very high radio frequency[J]. Plasma Sources Science and Technology, 2001, 10(3): 417-422. |
| [41] | CHEN F F. Helicon discharges and sources: A review[J]. Plasma Sources Science and Technology, 2015, 24(1): 014001. |
| [42] | BARNES R M, KOVA?I? N, MEYER G A. Computer simulation of a nitrogen ICP discharge[J]. Spectrochimica Acta Part B: Atomic Spectroscopy, 1985, 40(7): 907-918. |
| [43] | 谢维杰. 光谱解析低温等离子体中O2,N2,CO2的活性中间体及其环境化学行为[D]. 上海: 上海交通大学, 2008: 28-39. |
| XIE W J. Spectroscopic diagnostics of active species and their environmental chemical process of O2 , N2, CO2 in cold plasma[D]. Shanghai: Shanghai Jiao Tong University, 2008: 28-39 (in Chinese). |
/
| 〈 |
|
〉 |
CJA