Simulations of atmospheric pressure discharge in a high-voltage nanosecond pulse using the particle-in-cell Monte Carlo collision model in noble gases

Physics of Plasmas

Volumn 15, Issue 6, 2008, Pages

  Shi, Feng ^a   Wang, Dezhen ^a   Ren, Chunsheng ^a  

^a DALIAN UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

[No Author keywords available]

Indexed keywords

ARGON; ATMOSPHERIC PRESSURE; ATMOSPHERICS; AVALANCHES (SNOWSLIDES); CLIMATOLOGY; CONFORMAL MAPPING; CURRENT DENSITY; DISCHARGE (FLUID MECHANICS); DISTRIBUTION FUNCTIONS; ELECTRIC DISCHARGES; FLUID MECHANICS; FUNCTION EVALUATION; HELIUM; ION BEAMS; IONIZATION OF GASES; METEOROLOGY; MONTE CARLO METHODS; PLASMA APPLICATIONS; PLASMAS; PRESSURE; SNOW; TREES (MATHEMATICS);

(OTDR) TECHNOLOGY; AMERICAN INSTITUTE OF PHYSICS (AIP); APPLIED (CO); ATMOSPHERIC PRESSURE DISCHARGES; DOUBLE PEAKS; ELECTRON AND ION ENERGY DISTRIBUTION; FUNCTION OF TIME; HIGH-VOLTAGE (HV); INDEPENDENCE (PERSONALITY); MAPPING ALGORITHMS; MONTE CARLO COLLISION; NANOSECOND PULSES; NON-EQUILIBRIUM PLASMA; NUMERICA L RESULTS; ONE ATMOSPHERIC PRESSURE; ONE-DIMENSIONAL; PARTICLE-IN-CELL (PIC); PLASMA PROCESSING; RENORMALIZATION; REVERSE FIELD; TOTAL CURRENT; WEIGHTING PROCEDURE;

INERT GASES;

EID: 46349099139     PISSN: 1070664X     EISSN: None     Source Type: Journal    
DOI: 10.1063/1.2927437     Document Type: Article

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