Viscosity, SecondpVT-Virial Coefficient, and Diffusion of Pure and Mixed Small Alkanes CH4, C2H6, C3H8,n-C4H10,i-C4H10,n-C5H12,i-C5H12, and C(CH3)4 Calculated by Means of an Isotropic Temperature-Dependent Potential. I. Pure Alkanes

Zarkova, L.; Hohm, Uwe; Damyanova, M

doi:10.1063/1.2201308

Cited by 27 publications

(16 citation statements)

References 147 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Finally, Fig. 2 also shows a comparison with values recommended as reference data by Zarkova et al 63 These values were calculated via an isotropic three-parameter Lennard-Jones ͑n − 6͒ potential obtained from a multiproperty fit to experimental data for the second pressure and acoustic virial coefficients, as well as for viscosity and selfdiffusion at low density. They agree neither with the calculated values nor with the experimental data and hence cannot be considered as standard viscosity values for methane.…”

Section: Comparison With Experimentsmentioning

confidence: 90%

Calculation of the transport and relaxation properties of methane. I. Shear viscosity, viscomagnetic effects, and self-diffusion

Hellmann

Bich

Vogel

et al. 2008

The Journal of Chemical Physics

View full text Add to dashboard Cite

Transport properties of pure methane gas have been calculated in the rigid-rotor approximation using the recently proposed intermolecular potential energy hypersurface [R. Hellmann et al., J. Chem. Phys. 128, 214303 (2008)] and the classical-trajectory method. Results are reported in the dilute-gas limit for shear viscosity, viscomagnetic coefficients, and self-diffusion in the temperature range of 80-1500 K. Compared with the best measurements, the calculated viscosity values are about 0.5% too high at room temperature, although the temperature dependence of the calculated values is in very good agreement with experiment between 210 and 390 K. For the shear viscosity, the calculations indicate that the corrections in the second-order approximation and those due to the angular-momentum polarization are small, less than 0.7%, in the temperature range considered. The very good agreement of the calculated values with the experimental viscosity data suggests that the rigid-rotor approximation should be very reasonable for the three properties considered. In general, the agreement for the other measured properties is within the experimental error.

show abstract

Section: Comparison With Experimentsmentioning

confidence: 90%

Calculation of the transport and relaxation properties of methane. I. Shear viscosity, viscomagnetic effects, and self-diffusion

Hellmann

Bich

Vogel

et al. 2008

The Journal of Chemical Physics

View full text Add to dashboard Cite

show abstract

“…On the contrary, the data of Douslin et al 32 show virtually no differences to the EOS, because they were used to determine the equation. Figure 5 also shows a comparison with values recommended as reference data by Zarkova et al 46 In the case of methane the basis for these values is an isotropic threeparameter Lennard-Jones-͑n −6͒ potential obtained from a multiproperty fit to experimental data for the second pressure and acoustic virial coefficients as well as for viscosity and self-diffusion at low density. Figure 5 also shows a comparison with values recommended as reference data by Zarkova et al 46 In the case of methane the basis for these values is an isotropic threeparameter Lennard-Jones-͑n −6͒ potential obtained from a multiproperty fit to experimental data for the second pressure and acoustic virial coefficients as well as for viscosity and self-diffusion at low density.…”

Section: Adjustment Of the Intermolecular Potential Energy Surfacmentioning

confidence: 94%

Ab initio intermolecular potential energy surface and second pressure virial coefficients of methane

Hellmann

Bich

Vogel

2008

The Journal of Chemical Physics

104

View full text Add to dashboard Cite

A six-dimensional potential energy hypersurface (PES) for two interacting rigid methane molecules was determined from high-level quantum-mechanical ab initio computations. A total of 272 points for 17 different angular orientations on the PES were calculated utilizing the counterpoise-corrected supermolecular approach at the CCSD(T) level of theory with basis sets of aug-cc-pVTZ and aug-cc-pVQZ qualities. The calculated interaction energies were extrapolated to the complete basis set limit. An analytical site-site potential function with nine sites per methane molecule was fitted to the interaction energies. In addition, a semiempirical correction to the analytical potential function was introduced to take into account the effects of zero-point vibrations. This correction includes adjustments of the dispersion coefficients and of a single-parameter within the fit to the measured values of the second virial coefficient B(T) at room temperature. Quantitative agreement was then obtained with the measured B values over the whole temperature range of the measurements. The calculated B values should definitely be more reliable at very low temperatures (T<150 K) than values extrapolated using the currently recommended equation of state.

show abstract

“…Model inadequacy can sometimes be seen as a consequence of the use of a unique parameter set in different experimental conditions: a "better" model can indeed be obtained by using different values of the parameters along the control space. This can be achieved by modeling the dependence of the physical parameters on the control variable, [75][76][77] or by splitting the data in series along the control space and using a hierarchical model identical to the one in Section 3.2.2.2 for inference of the hyperparameters describing the model's parameters distribution (model M H2 in Wu et al 9 ). To differentiate both hierarchical schemes, the present one is named HierC.…”

Section: Hierc: Local Parameters In Control Spacementioning

confidence: 99%

A critical review of statistical calibration/prediction models handling data inconsistency and model inadequacy

Pernot

Cailliez

2017

AIChE Journal

View full text Add to dashboard Cite

Inference of physical parameters from reference data is a well studied problem with many intricacies (inconsistent sets of data due to experimental systematic errors; approximate physical models...). The complexity is further increased when the inferred parameters are used to make predictions -virtual measurements -because parameters uncertainty has to be estimated in addition to parameters best value. The literature is rich in statistical models for the calibration/prediction problem, each having benefits and limitations.We review and evaluate standard and state-of-the-art statistical models in a common bayesian framework, and test them on synthetic and real datasets of temperaturedependent viscosity for the calibration of Lennard-Jones parameters of a ChapmanEnskog model.

show abstract

Viscosity, SecondpVT-Virial Coefficient, and Diffusion of Pure and Mixed Small Alkanes CH4, C2H6, C3H8,n-C4H10,i-C4H10,n-C5H12,i-C5H12, and C(CH3)4 Calculated by Means of an Isotropic Temperature-Dependent Potential. I. Pure Alkanes

Cited by 27 publications

References 147 publications

Calculation of the transport and relaxation properties of methane. I. Shear viscosity, viscomagnetic effects, and self-diffusion

Calculation of the transport and relaxation properties of methane. I. Shear viscosity, viscomagnetic effects, and self-diffusion

Ab initio intermolecular potential energy surface and second pressure virial coefficients of methane

A critical review of statistical calibration/prediction models handling data inconsistency and model inadequacy

Contact Info

Product

Resources

About