The use of quantum chemistry to predict phase behavior for environmental and process engineering

Fluid Phase Equilibria

Volumn 194-197, Issue , 2002, Pages 61-75

  Sandler, Stanley I ^a   Lin, Shiang Tai ^a   Sum, Amadeu K ^a  

^a University of Delaware   (United States)

Author keywords

Environment; Fugacity; Molecular simulation; Octanol water partitioning; Quantum mechanics; Solvation

Indexed keywords

AIR; ENVIRONMENTAL ENGINEERING; SOILS; THERMODYNAMIC PROPERTIES; VAPOR PRESSURE; WATER;

QUANTUM CHEMISTRY;

PROCESS ENGINEERING;

OCTANOL; WATER;

ENVIRONMENTAL IMPACT; PHASE EQUILIBRIUM MODEL; QUANTUM MECHANICS;

AIR; ATOM; CHEMICAL ENGINEERING; COMPUTER SIMULATION; CONFERENCE PAPER; DILUTION; ENVIRONMENT; MATHEMATICAL MODEL; PARTITION COEFFICIENT; PREDICTION; QUANTUM CHEMISTRY; SOIL; SOLVATION; THERMODYNAMICS; VAPOR PRESSURE;

EID: 0037196739     PISSN: 03783812     EISSN: None     Source Type: Journal    
DOI: 10.1016/S0378-3812(01)00643-4     Document Type: Conference Paper

References (29)

1. Symmerty-adapted perturbation theory of intermolecular interactions
2. Intermolecular interactions by perturbation theory