Evolution of Ar Plasma Under Different Initial Temperatures

WANG Feng; HE Li-ming; LAN Yu-dan; DU Hong-liang; YU Jian

doi:10.7538/yzk.2011.45.05.0624

Atomic Energy Science and Technology > 2011 > 45(5): 624-627. > DOI: 10.7538/yzk.2011.45.05.0624

WANG Feng, HE Li-ming, LAN Yu-dan, DU Hong-liang, YU Jian. Evolution of Ar Plasma Under Different Initial Temperatures[J]. Atomic Energy Science and Technology, 2011, 45(5): 624-627. DOI: 10.7538/yzk.2011.45.05.0624

Citation:

PDF (397 KB)

Evolution of Ar Plasma Under Different Initial Temperatures

1.
Engineering Institute, Air Force Engineering University, Xi’an 710038, China
2.
China Oilfield Services Limited, Sanhe 065200, China

More Information

Received Date: December 31, 1899
Revised Date: December 31, 1899

Graphical Abstract

Abstract

Abstract

This work carried on a numerical simulation of evolution laws of the main particles in Ar plasma with time-variation under different initial temperatures. The changes of concentration of various main particles with time-variation were tracked, and the evolution laws of concentration of main charged and neutral particles in discharged Ar plasma were obtained. The results show that the time required for Ar plasma chemical reaction to reach equilibrium is reduced with the increasing of initial temperature. The concentration of active particle Ar⁺increases with time, the concentration of Ar^*, Ar^** firstly increases and then decreases with time, and finally reaches equilibrium.
- Ar plasma,
- particle concentration,
- numerical simulation,
- evolution law

FullText(HTML)

References (15)

References

[1]	董丽芳，冉俊霞，尹增谦，等. 大气压氩气介质阻挡放电中的电子激发温度[J]. 光谱学与光谱分析，2005，25(8)：1 184-1 186. DONG Lifang, RAN Junxia, YIN Zengqian, et al. Electron excitation temperature of argon dielectric barrier discharge at atmospheric pressure[J]. Spectroscopy and Spectral Analysis, 2005, 25(8): 1 184-1 186(in Chinese).
[2]	杨赛丹，王霞敏，陈扬骎，等. OH分子束产生及其相关特性研究[J]. 原子与分子物理学报，2006，23(5)：791-796. YANG Saidan, WANG Xiamin, CHEN Yangqin, et al. Study on the generation and features of OH molecular beam[J]. Journal of Atomic and Molecular Physics, 2006, 23(5): 791-796(in Chinese).
[3]	PETSCHEK H E，ROSE P H, GLICK H S. Spectroscopic studies of highly ionized argon produced by shock waves[J]. J Appl Phys, 1955, 26(1): 83-95.
[4]	FORTOV V E. Dynamic methods in plasma physics[J]. Sovphys Uspekhi, 1982, 25(11): 781-809.
[5]	ERSKINE D. Measuring opacity of shock generated argon plasma[J]. J Quant Spectrosc Radiant Transfer, 1994, 51(1/2): 97-100.
[6]	彭其先，胡绍楼，唐敬友. 冲击光谱的多通道时间分辨测量[J]. 光电子激光，2001(2)：1 051-1 053. PENG Qixian, HU Shaolou, TANG Jingyou. Spectrum measuring under shock with multi-channel time-resolution[J]. Journal of Optoelectronics Laser, 2001(2): 1 051-1 053(in Chinese).
[7]	牛田野，曹金祥，刘磊，等. 低温氩等离子体中的单探针和发射光谱诊断技术[J]. 物理学报，2007，56(4)：2 330-2 336. NIU Tianye, CAO Jinxiang, LIU Lei, et al. The techniques of single probe and emission spectroscopy diagnostics in low temperature argon plasmas[J]. Acta Physica Sinica, 2007, 56(4): 2 330-2 336(in Chinese).
[8]	GUDMUNDSSON J T. THORSTEINSSON E G. On the role of argon reactions in a low pressure Ar/O₂discharge[C] ∥28th ICPIG. Prague, Czech Republic: [s. n.], 2007: 79-82.
[9]	GUDMUNDSSON J T, THORSTEINSSON E G. Oxygen discharges diluted with argon: Dissociation processes [J]. Plasma Sources Science and Technolgy, 2007, 16(2): 399.
[10]	SALESKY E T. Kinetics modeling and interpretation of experimental results for XeF[R]. US: Los Alamos National Laboratory, 1986.
[11]	LORENTS D C. The physics of electron beam excited rare gases at high densities[J]. Physica C, 1976, 82: 19-26.
[12]	LEICHNER P K, ERICSON R J. Time dependence of vacuum ultraviolet emissions in krypton excited by 250 keV electrons[J]. Phys Rev A, 1974, 9: 251-259.
[13]	OSKAM H J, MITTELSTADT V R. Recombination coefficient of molecular rare-gas ions[J]. Phys Rev, 1963, 132: 1 445-1 454.
[14]	SHIBKOV V M, KONSTANTINOVSKIJ R S. Kinetic model of ignition of hydrogen-oxygen mixture under conditions of non-equilibrium plasma of the gas discharge, AIAA [R]. [S. l.] : [s. n.], 2005.
[15]	WESTBROOK C K. CHASE L L. Chemical kinetics and thermochemical data for combustion application[R]. California: Lawrence Livermore Laboratory, 1978.

Cited By

Cited by

Periodical cited type(8)

1.	涂细凯，王一举，陆浩，李肖. 下肢外骨骼步态自适应助力控制研究. 机械设计与制造. 2025(01): 302-306+312 .
2.	邵志元. 振动干扰下大负载DJ型架桥机机臂升降液压稳态控制. 机械制造与自动化. 2025(01): 251-255 .
3.	李科莹. 基于PSO优化的模糊控制器在选择性催化还原脱硝技术中的应用. 自动化应用. 2024(07): 97-99+108 .
4.	付晓，徐锐良，闫祥海，徐立友. 力位综合系数调节方法研究. 中国农机化学报. 2024(06): 37-41 .
5.	高靖茹，高燃，刘硕林，李哲轩，江家辉，杜佳岭. 基于模糊控制算法的软体机器人系统. 现代信息科技. 2024(20): 111-116 .
6.	郑显润，胡睿，梁刚刚，孙亚飞. 旋转调制惯导系统转位机构的高精度控制研究. 弹箭与制导学报. 2024(05): 47-53 .
7.	王凯，朱慧珍，王丽君. 深度学习理论下移动机器人全局路径规划方法. 计算机仿真. 2023(10): 431-434+439 .
8.	侯军凯，聂建军，牛继高，席建普，闫修鹏. 基于微控制器的模糊控制算法实现. 中原工学院学报. 2021(05): 57-62 .

Other cited types(11)

Get Citation

PDF

XML

Article views (783) PDF downloads (990) Cited by(19)

Turn off MathJax

Article Contents

Abstract

References

Evolution of Ar Plasma Under Different Initial Temperatures

Abstract

References

Cited by

Periodical cited type(8)

Other cited types(11)

Catalog

Export File

Citation

Format

Content