Viscosity of {xCO2+(1−x)CH4} with x=0.5174 for temperatures between (229 and 348)K and pressures between (1 and 32)MPa

•New viscosity data for CO2+CH4 are reported for a wide range of (T,p).•The new measurements are consistent with and extend literature viscosity data.•The new data deviate systematically by up to 16% from two extended corresponding states models.•A molecular dynamics corresponding states model repro...

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Bibliographic Details
Published inThe Journal of chemical thermodynamics Vol. 87; pp. 162 - 167
Main Authors Locke, Clayton R., Stanwix, Paul L., Hughes, Thomas J., Johns, Michael L., Goodwin, Anthony R.H., Marsh, Kenneth N., Galliero, Guillaume, May, Eric F.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.08.2015
Subjects
Carbon dioxide
Corresponding states
Density
Methane
Molecular dynamics
Viscosity
Viscosity
Methane
Molecular dynamics
Corresponding states
Density
Carbon dioxide
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Summary:•New viscosity data for CO2+CH4 are reported for a wide range of (T,p).•The new measurements are consistent with and extend literature viscosity data.•The new data deviate systematically by up to 16% from two extended corresponding states models.•A molecular dynamics corresponding states model reproduces the data within 4.2%. A vibrating wire instrument, in which the wire was clamped at both ends, was used to measure the viscosity of {xCO2+(1−x)CH4} with x=0.5174 with a combined uncertainty of 0.24μPa·s (a relative uncertainty of about 0.8%) at temperatures T between (229 and 348)K and pressures p from (1 to 32)MPa. The corresponding mass density ρ, estimated with the GERG-2008 equation of state, varied from (20 to 600)kg·m−3. The measured viscosities were consistent within combined uncertainties with data obtained previously for this system using entirely different experimental techniques. The new data were compared with three corresponding states-type models frequently used for predicting mixture viscosities: the Extended Corresponding States (ECS) model implemented in REFPROP 9.1; the SUPERTRAPP model implemented in MultiFlash 4.4; and a corresponding states model derived from molecular dynamics simulations of Lennard Jones fluids. The measured viscosities deviated systematically from the predictions of both the ECS and SUPERTRAPP models with a maximum relative deviations of 11% at (229K, 600kg·m−3) and −16% at (258K, 470kg·m−3), respectively. In contrast, the molecular dynamics based corresponding states model, which is predictive for mixtures in that it does not contain any binary interaction parameters, reproduced the density and temperature dependence of the measured viscosities well, with relative deviations of less than 4.2%.
ISSN:0021-9614
1096-3626
DOI:10.1016/j.jct.2015.03.007