A stochastic approach for the numerical simulation of the general dynamics equation for aerosols

Journal of Computational Physics

Volumn 184, Issue 2, 2003, Pages 649-669

  Debry, Edouard ^a   Sportisse, Bruno ^a   Jourdain, Benjamin ^b  

^a UNIVERSITÉ PARIS EST   (France)

^b UNIVERSITÉ PARIS EST   (France)

Author keywords

Aerosol size density; Air pollution modeling; Atmospheric aerosols; Coagulation; Condensation; Evaporation; General dynamics equation; Nucleation; Size resolved methods; Stochastic resolution

Indexed keywords

APPROXIMATION ALGORITHMS; ATMOSPHERIC AEROSOLS; CONDENSATION; DYNAMICS; MONTE CARLO METHODS; NUMERICAL METHODS; PARTICLE SIZE ANALYSIS; STOCHASTIC SYSTEMS;

AEROSOL SIZE; AEROSOL SIZE DENSITY; AIR POLLUTION MODELS; GENERAL DYNAMIC EQUATION; MONTECARLO METHODS; SIZE-RESOLVED METHOD; STOCHASTIC ALGORITHMS; STOCHASTIC APPROACH; STOCHASTIC RESOLUTION; STOCHASTICS;

COAGULATION;

EID: 0037455651     PISSN: 00219991     EISSN: None     Source Type: Journal    
DOI: 10.1016/S0021-9991(02)00041-4     Document Type: Article

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