Application of several activity coefficient models to water-organic-electrolyte aerosols of atmospheric interest
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[1] R. Robinson,et al. Interactions in Aqueous Nonelectrolyte Solutions. I. Solute-Solvent Equilibria , 1966 .
[2] Peter Brimblecombe,et al. Thermodynamic Model of the System H+−NH4+−SO42-−NO3-−H2O at Tropospheric Temperatures , 1998 .
[3] Jürgen Gmehling,et al. A gE model for single and mixed solvent electrolyte systems: 1. Model and results for strong electrolytes , 1994 .
[4] Y. Ming,et al. Thermodynamic equilibrium of organic‐electrolyte mixtures in aerosol particles , 2002 .
[5] W. M. Haynes. CRC Handbook of Chemistry and Physics , 1990 .
[6] C. Chan,et al. The hygroscopic properties of dicarboxylic and multifunctional acids: measurements and UNIFAC predictions. , 2001, Environmental science & technology.
[7] S. Kreidenweis,et al. Water uptake of internally mixed particles containing ammonium sulfate and dicarboxylic acids , 2003 .
[8] C. Dussap,et al. Representation of vapour -liquid equilibria in water-alcohol-electrolyte mixtures with a modified UNIFAC group-contribution method , 1994 .
[9] Jürgen Gmehling,et al. Prediction of vapor-liquid equilibria in mixed-solvent electrolyte systems using the group contribution concept , 1999 .
[10] J. A. Rard,et al. Critical Evaluation of the Thermodynamic Properties of Aqueous Calcium Chloride. 1. Osmotic and Activity Coefficients of 0−10.77 mol·kg-1 Aqueous Calcium Chloride Solutions at 298.15 K and Correlation with Extended Pitzer Ion-Interaction Models , 1997 .
[11] Eli Korin,et al. The vapour pressures of saturated aqueous solutions of sodium chloride, sodium bromide, sodium nitrate, sodium nitrite, potassium iodate, and rubidium chloride at temperatures from 227 K to 323 K , 1998 .
[12] S. Pandis,et al. Deliquescence and Hygroscopic Growth of Mixed Inorganic−Organic Atmospheric Aerosol , 2000 .
[13] W. Hamer,et al. Osmotic Coefficients and Mean Activity Coefficients of Uni‐univalent Electrolytes in Water at 25°C , 1972 .
[14] B. J. Levien. A Physicochemical Study of Aqueous Citric Acid Solutions. , 1955 .
[15] Peter Brimblecombe,et al. Thermodynamics of multicomponent, miscible, ionic solutions. Mixtures including unsymmetrical electrolytes , 1992 .
[16] E. Macedo,et al. Experimental measurement and modelling of KBr solubility in water, methanol, ethanol, and its binary mixed solvents at different temperatures , 2002 .
[17] J. A. Rard,et al. Isopiestic determination of the osmotic and activity coefficients ofZnSO4(aq) atT = 298.15 K, and the standard potential of the electrochemical cell ZnHgx(two phase)| ZnSO4(aq)| PbSO4(s)| PbHgx(two phase) , 2000 .
[18] J. Wisniak,et al. The vapour pressure of water over saturated aqueous solutions of malic, tartaric, and citric acids, at temperatures from 288 K to 323 K , 1995 .
[19] John A. Nelder,et al. A Simplex Method for Function Minimization , 1965, Comput. J..
[20] S. Pandis,et al. Prediction of multicomponent inorganic atmospheric aerosol behavior , 1999 .
[21] M. Iliuta,et al. Extended UNIQUAC model for correlation and prediction of vapour–liquid–solid equilibria in aqueous salt systems containing non-electrolytes. Part A. Methanol–water–salt systems , 2000 .
[22] A. Sereno,et al. Measurement and prediction of water activity in electrolyte solutions by a modified ASOG group contribution method , 1997 .
[23] P. Brimblecombe,et al. Application of a Multicomponent Thermodynamic Model to Activities and Thermal Properties of 0-40 mol kg-1 Aqueous Sulfuric Acid from <200 to 328 K , 1995 .
[24] M. Tolbert,et al. Deliquescence behavior of organic/ammonium sulfate aerosol , 2002 .
[25] M. Born. Statistical Thermodynamics , 1944, Nature.
[26] Kaj Thomsen,et al. Modeling of vapor-liquid-solid equilibrium in gas - aqueous electrolyte systems , 1999 .
[27] M. Guendouzi,et al. Water activities, osmotic and activity coefficients in aqueous chloride solutions atT = 298.15 K by the hygrometric method , 2001 .
[28] M. Guendouzi,et al. Determination of water activities, osmotic and activity coefficients in aqueous solutions using the hygrometric method , 2000 .
[29] K. Beyer,et al. Experimentally Determined Thermochemical Properties of the Malonic Acid/Water System: Implications for Atmospheric Aerosols , 2004 .
[30] J. Prausnitz,et al. Statistical thermodynamics of liquid mixtures: A new expression for the excess Gibbs energy of partly or completely miscible systems , 1975 .
[31] A. Wexler,et al. Thermodynamic Model of the System H+−NH4+−Na+−SO42-−NO3-−Cl-−H2O at 298.15 K , 1998 .
[32] Rafiqul Gani,et al. Correlation and prediction of thermal properties and phase behaviour for a class of aqueous electrolyte systems , 1996 .
[33] J. Seinfeld,et al. On the Hygroscopic Behavior of Atmospheric Organic Aerosols , 2001 .
[34] Peter Brimblecombe,et al. Thermodynamic modelling of aqueous aerosols containing electrolytes and dissolved organic compounds , 2001 .
[35] M. Guendouzi,et al. Water activity, osmotic and activity coefficients of aqueous solutions of Li2SO4, Na2SO4, K2SO4, (NH4)2SO4, MgSO4, MnSO4, NiSO4, CuSO4, and ZnSO4 at T=298.15 K , 2003 .
[36] E. Korin,et al. The vapour pressure of water over saturated solutions of sodium sulfate, calcium bromide, ferric chloride, zinc nitrate, calcium nitrate, and lithium nitrate at temperatures from 278.15 K to 323.15 K , 2002 .
[37] E. Korin,et al. Vapour pressures of saturated aqueous solutions of ammonium iodide, potassium iodide, potassium nitrate, strontium chloride, lithium sulphate, sodium thiosulphate, magnesium nitrate, and uranyl nitrate fromT=(278 to 323) K , 1998 .
[38] J. Penner,et al. Large contribution of organic aerosols to cloud-condensation-nuclei concentrations , 1993, Nature.
[39] H. Hansson,et al. Hygroscopic properties of mixed ammonium sulfate and carboxylic acids particles , 2002 .
[40] J. Seinfeld,et al. Atmospheric Chemistry and Physics: From Air Pollution to Climate Change , 1997 .
[41] C. Chan,et al. The effects of organic species on the hygroscopic behaviors of inorganic aerosols. , 2002, Environmental science & technology.
[42] Thomas Peter,et al. Mixing of the Organic Aerosol Fractions: Liquids as the Thermodynamically Stable Phases , 2004 .
[43] A. J. Meirelles,et al. Water Activity and pH in Aqueous Polycarboxylic Acid Systems , 2001 .
[44] Aage Fredenslund,et al. A modified UNIFAC group-contribution model for prediction of phase equilibria and heats of mixing , 1987 .
[45] G. Maurer,et al. Activity of Water in Aqueous Solutions of Sodium Citrate and in Aqueous Solutions of (An Inorganic Salt and Citric Acid) at 298.15 K , 2004 .
[46] L. Greenspan. Humidity Fixed Points of Binary Saturated Aqueous Solutions , 1977, Journal of Research of the National Bureau of Standards. Section A, Physics and Chemistry.
[47] T. Onasch,et al. Deliquescence, Efflorescence, and Water Activity in Ammonium Nitrate and Mixed Ammonium Nitrate/Succinic Acid Microparticles , 2000 .
[48] P. Saxena,et al. Water-soluble organics in atmospheric particles: A critical review of the literature and application of thermodynamics to identify candidate compounds , 1996 .
[49] P. Brimblecombe,et al. Equilibrium partial pressures and mean activity and osmotic coefficients of 0-100 % nitric acid as a function of temperature , 1990 .
[50] Aage Fredenslund,et al. Vapor−Liquid Equilibria by UNIFAC Group Contribution. 6. Revision and Extension , 1979 .
[51] D. Topping,et al. A curved multi-component aerosol hygroscopicity model framework : 2 – Including organics , 2004 .
[52] Judith C. Chow,et al. Temporal and spatial variations of PM2.5 and PM10 aerosol in the Southern California air quality study , 1994 .
[53] C. Srinivasakannan,et al. A Study on Crystallization of Oxalic Acid in Batch Cooling Crystallizer , 2002 .
[54] Aage Fredenslund,et al. Group‐contribution estimation of activity coefficients in nonideal liquid mixtures , 1975 .
[55] S. Yamagata,et al. Activation capability of water soluble organic substances as CCN , 2003 .