Your search keyword '"V. B. Savarin"' showing total 3 results

1. A new inorganic atmospheric aerosol phase equilibrium model (UHAERO)

Author

N. R. Amundson, A. Caboussat, J. W. He, A. V. Martynenko, V. B. Savarin, J. H. Seinfeld, and K. Y. Yoo

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

A variety of thermodynamic models have been developed to predict inorganic gas-aerosol equilibrium. To achieve computational efficiency a number of the models rely on a priori specification of the phases present in certain relative humidity regimes. Presented here is a new computational model, named UHAERO, that is both efficient and rigorously computes phase behavior without any a priori specification. The computational implementation is based on minimization of the Gibbs free energy using a primal-dual method, coupled to a Newton iteration. The mathematical details of the solution are given elsewhere. The model computes deliquescence behavior without any a priori specification of the relative humidities of deliquescence. Also included in the model is a formulation based on classical theory of nucleation kinetics that predicts crystallization behavior. Detailed phase diagrams of the sulfate/nitrate/ammonium/water system are presented as a function of relative humidity at 298.15 K over the complete space of composition.

Published

2006

2. A new inorganic atmospheric aerosol phase equilibrium model (UHAERO)

Author

Jiwen He, Alexandre Caboussat, V. B. Savarin, A. V. Martynenko, John H. Seinfeld, Kee-Youn Yoo, and Neal R. Amundson

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Chemistry, Thermodynamics, Function (mathematics), 010501 environmental sciences, 01 natural sciences, Gibbs free energy, Aerosol, symbols.namesake, Phase (matter), symbols, A priori and a posteriori, Relative humidity, Statistical physics, Newton's method, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Phase diagram

Abstract

A variety of thermodynamic models have been developed to predict inorganic gas-aerosol equilibrium. To achieve computational efficiency a number of the models rely on a priori specification of the phases present in certain relative humidity regimes. Presented here is a new computational model, named UHAERO, that is both efficient and rigorously computes phase behavior without any a priori specification. The computational implementation is based on minimization of the Gibbs free energy using a primal-dual method, coupled to a Newton iteration. The mathematical details of the solution are given elsewhere. The model computes deliquescence behavior without any a priori specification of the relative humidities of deliquescence. Also included in the model is a formulation based on classical theory of nucleation kinetics that predicts crystallization behavior. Detailed phase diagrams of the sulfate/nitrate/ammonium/water system are presented as a function of relative humidity at 298.15 K over the complete space of composition.

Published

2006

3. A computationally efficient inorganic atmospheric aerosol phase equilibrium model (UHAERO)

Author

Kee-Youn Yoo, A. V. Martynenko, Jiwen He, John H. Seinfeld, V. B. Savarin, Neal R. Amundson, and Alexandre Caboussat

Subjects

010504 meteorology & atmospheric sciences, Chemistry, Thermodynamics, Function (mathematics), 010501 environmental sciences, 01 natural sciences, Gibbs free energy, Aerosol, symbols.namesake, Phase (matter), symbols, A priori and a posteriori, Applied mathematics, Relative humidity, Newton's method, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Phase diagram

Abstract

A variety of thermodynamic models have been developed to predict inorganic gas-aerosol equilibrium. To achieve computational efficiency a number of the models rely on a priori specification of the phases present in certain relative humidity regimes. Presented here is a new computational model, named UHAERO, that is both efficient and rigorously computes phase behavior without any a priori specification. The computational implementation is based on minimization of the Gibbs free energy using a primal-dual method, coupled to a Newton iteration. The mathematical details of the solution are given elsewhere. The model also computes deliquescence and crystallization behavior without any a priori specification of the relative humidities of deliquescence or crystallization. Detailed phase diagrams of the sulfate/nitrate/ammonium/water system are presented as a function of relative humidity at 298.15 K over the complete space of composition.

Published

2005