| 1 |
Prediction of properties of new halogenated olefins using two group contribution approaches
Mondejar ME, Cignitti S, Abildskov J, Woodley JM, Haglind F
Fluid Phase Equilibria, 433, 79, 2017 |
| 2 |
Vapor pressure and gaseous speed of sound measurements for isobutane (R600a)
Liu Q, Feng XJ, Zhang K, An BL, Duan YY
Fluid Phase Equilibria, 382, 260, 2014 |
| 3 |
Predictive correlations for ideal gas heat capacities of pure hydrocarbons and petroleum fractions
Lastovka V, Shaw JM
Fluid Phase Equilibria, 356, 338, 2013 |
| 4 |
Improvement on multiparameter equations of state for dimethylsiloxanes by adopting more accurate ideal-gas isobaric heat capacities: Supplementary to P. Colonna, NR Nannan, A. Guardone, EW Lemmon, Fluid Phase Equilib. 244,193 (2006)
Nannan NR, Colonna P
Fluid Phase Equilibria, 280(1-2), 151, 2009 |
| 5 |
Use of transformed correlations to help screen and populate properties within databanks
Morgan DL
Fluid Phase Equilibria, 256(1-2), 54, 2007 |
| 6 |
Ideal-gas heat capacities of dimethylsiloxanes from speed-of-sound measurements and ab initio calculations
Nannan NR, Colonna P, Tracy CM, Rowley RL, Hurly JJ
Fluid Phase Equilibria, 257(1), 102, 2007 |
| 7 |
Comparison of ab initio and group additive ideal gas heat capacities
Marriott RA, White MA
AIChE Journal, 51(1), 292, 2005 |
| 8 |
Determination of a vapour phase Helmholtz equation for 1,1,1-trifluoroethane (HFC-143a) from speed of sound measurements
Scalabrin G, Marchi P, Benedetto G, Gavioso RM, Spagnolo R
Journal of Chemical Thermodynamics, 34(10), 1601, 2002 |
| 9 |
Quantum mechanical calculations of molecular properties and ideal gas heat capacity of difluoromethane
Speis M, Delfs U, Lucas K
Fluid Phase Equilibria, 170(2), 285, 2000 |
| 10 |
Vapor phase acoustic measurements for R125 and development of a Helmholtz free energy equation
Grigiante M, Scalabrin G, Benedetto G, Gavioso RM, Spagnolo R
Fluid Phase Equilibria, 174(1-2), 69, 2000 |
