Gaurav Kumar Kedia scite author profile

Vapour-liquid equilibria of the Lennard-Jones potential, truncated and shifted at 2:5, are studied using molecular dynamics simulations, an attractive option for studying inhomogeneous systems. Comprehensive simulation data are reported for three cases: no interface, a planar interface, and a spherical interface between the coexisting phases, covering a wide range of temperatures. Spherical droplets are also studied for a range of radii between 5 and 16. The size dependence of the surface tension, based on the Irving-Kirkwood pressure tensor, and other properties is quantified for spherical interfaces. All simulation results are correlated with a consistent set of empirical equations. A comparison with the results of other authors as well as with experimental data for noble gases and methane is also presented.

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Prediction of Joule–Thomson inversion curves for pure fluids and one mixture by molecular simulation

Vrabec

Kedia

Hasse

2005

Cryogenics

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Thermodynamic models for vapor–liquid equilibria of nitrogen+oxygen+carbon dioxide at low temperatures

Vrabec¹,

Kedia²,

Buchhauser³

et al. 2009

Cryogenics

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For the design and optimization of CO 2 recovery from alcoholic fermentation processes by distillation, models for vapor-liquid equilibria (VLE) are needed. Two such thermodynamic models, the Peng-Robinson equation of state (EOS) and a model based on Henry's law constants, are proposed for the ternary mixture N 2 +O 2 +CO 2 .Pure substance parameters of the Peng-Robinson EOS are taken from the literature, whereas the binary parameters of the Van der Waals one-fluid mixing rule are adjusted to experimental binary VLE data. The Peng-Robinson EOS describes both binary and ternary experimental data well, except at high pressures approaching the critical region. A molecular model is validated by simulation using binary and ternary experimental VLE data. On the basis of this model, the Henry's law constants of N 2 and O 2 in CO 2 are predicted by molecular simulation. An easy-touse thermodynamic model, based on those Henry's law constants, is developed to reliably describe the VLE in the CO 2 -rich region.

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