1 서준호, "플라즈마 풍동 시설용 분절형 아크 플라즈마 토치의 이론적 설계변수 해석" 한국추진공학회 15 (15): 85-93, 2011
2 Kim, K., "Time-Dependent One-Dimensional Modeling of Pulsed Plasma Discharge in a Capillary Plasma Device" 31 (31): 729-735, 2003
3 Rolader, G. E., "Thermodynamic and electrical properties of railgun plasma armatures" 17 (17): 439-445, 1989
4 Powell, J. D., "Theory and Experiment for an Ablating-Capillary Discharge and Applications to Electrothermal-Chemical Guns"
5 Li, R., "Study of Different Models of the Wall Ablation Process in Capillary Discharge" 38 (38): 1033-1041, 2010
6 Zaghloul, M. F., "Semi-Analytical Modelling and Simulation of the Evolution and Flow of Ohmically-Heated Non-Ideal Plasmas in Electrothermal Guns" 34 (34): 772-786, 2001
7 Dyvik, J., "Recent Activities in Electrothermal Chemical Launcher Technologies at BAE Systems" 43 (43): 303-307, 2007
8 White, K. J., "Plasma Characterization for Electrothermal-Chemical Gun Applications"
9 Kim, K., "Numerical Simulation of Capillary Plasma Flow Generated by High-Current Pulsed Power" 44 (44): 1039-1046, 2005
10 Raja, L. L., "Modeling of the Electrogun Metal Vapor Plasma Discharge" 11 (11): 353-360, 1997
1 서준호, "플라즈마 풍동 시설용 분절형 아크 플라즈마 토치의 이론적 설계변수 해석" 한국추진공학회 15 (15): 85-93, 2011
2 Kim, K., "Time-Dependent One-Dimensional Modeling of Pulsed Plasma Discharge in a Capillary Plasma Device" 31 (31): 729-735, 2003
3 Rolader, G. E., "Thermodynamic and electrical properties of railgun plasma armatures" 17 (17): 439-445, 1989
4 Powell, J. D., "Theory and Experiment for an Ablating-Capillary Discharge and Applications to Electrothermal-Chemical Guns"
5 Li, R., "Study of Different Models of the Wall Ablation Process in Capillary Discharge" 38 (38): 1033-1041, 2010
6 Zaghloul, M. F., "Semi-Analytical Modelling and Simulation of the Evolution and Flow of Ohmically-Heated Non-Ideal Plasmas in Electrothermal Guns" 34 (34): 772-786, 2001
7 Dyvik, J., "Recent Activities in Electrothermal Chemical Launcher Technologies at BAE Systems" 43 (43): 303-307, 2007
8 White, K. J., "Plasma Characterization for Electrothermal-Chemical Gun Applications"
9 Kim, K., "Numerical Simulation of Capillary Plasma Flow Generated by High-Current Pulsed Power" 44 (44): 1039-1046, 2005
10 Raja, L. L., "Modeling of the Electrogun Metal Vapor Plasma Discharge" 11 (11): 353-360, 1997
11 Weiss, E., "Modeling of Electrical Confined-Capillary-Discharge Where the Discharge Zone is Extended by an Additional Pipe" 373 (373): 972-975, 2009
12 Kohel, J. M., "Emission Spectroscopic Measurements and Analysis of a Pulsed Plasma Jet" 35 (35): 201-206, 1997
13 Kim, S. H., "Electrothermal-Chemical Ignition Research on 120-mm Gun in Korea" 45 (45): 341-346, 2009
14 Liebermann, R. W., "Electrical Conductivity of Nonideal Plasmas" 62 (62): 3621-3627, 1987
15 Peterson, D. R., "Design and Operation of the Electrogun, an Electrothermal Gun for Producing Metal and Carbon Plasma Jets" 33 (33): 373-378, 1997
16 Nusca, M. J., "Computational and Experimental Investigations of Open-Air Plasma Discharges" 1999
17 Li, R., "A Two-Dimensional Capillary Discharge Model Considering the Ablation and Deposition Processes" 110 (110): 1-6, 2011
18 Batteh, J., "A Methodology for Computing Thermodynamic and Transport Properties of Plasma Mixtures in ETC Injectors" 31 (31): 388-393, 1995