| 1 |
Liquid-liquid phase equilibrium and heat capacity of binary solution {2-propanol+1-octy1-3-methylimidazolium hexafluorophosphate}
Guo YM, Zhang XS, Xu C, Shen WG
Journal of Chemical Thermodynamics, 105, 434, 2017 |
| 2 |
Liquid-liquid equilibrium and heat capacity measurements of the binary solution {ethanol+1-butyl-3-methylimidazolium hexafluorophosphate}
Guo YM, Wang X, Tao XY, Shen WG
Journal of Chemical Thermodynamics, 115, 342, 2017 |
| 3 |
Measurements of the liquid-liquid phase equilibria of binary solutions of 1-methyl-3-octylimidazolium tetrafluoroborate with 1-heptanol or 2-pentanol
Zhang XS, Cui ZC, Yin TX, Zheng PZ, Zhao JH, Shen WG
Fluid Phase Equilibria, 394, 156, 2015 |
| 4 |
Computer simulations of charged colloids in confinement
Puertas AM, de las Nieves FJ, Cuetos A
Journal of Colloid and Interface Science, 440, 292, 2015 |
| 5 |
The thermodynamic properties prediction of aqueous ionic liquid ([Emim][X]) solutions by Monte Carlo simulation
Karimzadeh Z, Hosseini SAA, Deyhimi F
Fluid Phase Equilibria, 329, 86, 2012 |
| 6 |
Understanding physical properties of solutions using equation of state: Electrolyte systems
Pai SJ, Bae YC
Fluid Phase Equilibria, 332, 94, 2012 |
| 7 |
Modeling aqueous electrolyte solutions. Part 2. Weak electrolytes
Held C, Sadowski G
Fluid Phase Equilibria, 279(2), 141, 2009 |
| 8 |
Modeling aqueous electrolyte solutions - Part 1. Fully dissociated electrolytes
Held C, Cameretti LF, Sadowski G
Fluid Phase Equilibria, 270(1-2), 87, 2008 |
| 9 |
Monte Carlo study of the electrode solvent primitive model electrolyte interface
Lamperski S, Zydor A
Electrochimica Acta, 52(7), 2429, 2007 |
| 10 |
Application of the non-primitive MSA-based models in predicting the activity and the osmotic coefficients of aqueous electrolyte solutions
Seyfkar N, Ghotbi C, Taghikhani V, Azimi G
Fluid Phase Equilibria, 221(1-2), 189, 2004 |
