Dense fluid self-diffusion coefficient calculations using perturbation theory and molecular dynamics

A procedure to correlate self-diffusion coefficients in dense fluids by using the perturbation theory (WCA) coupled with the smooth-hard-sphere theory is presented and tested against molecular simulations and experimental data. This simple algebraic expression correlates well the self-diffusion coefficients of carbon dioxide, ethane, propane, ethylene, and sulfur hexafluoride. We have also performed canonical ensemble molecular dynamics simulations by using the Hoover-Nosé thermostat and the mean-square displacement formula to compute self-diffusion coefficients for the reference WCA intermolecular potential. The good agreement obtained from both methods, when compared with experimental data, suggests that the smooth-effective-sphere theory is a useful procedure to correlate diffusivity of pure substances.

Smooth-sphere theory; self-diffusion coefficient; molecular dynamics

Authorship

L. A. F. COELHO

UFRJ, Programa de Engenharia Química, PEQ/COPPE, Rio de Janeiro, RJ, BrazilUFRJBrazilRio de Janeiro, RJ, BrazilUFRJ, Programa de Engenharia Química, PEQ/COPPE, Rio de Janeiro, RJ, Brazil

J. V. OLIVEIRA

UFRJ, Programa de Engenharia Química, PEQ/COPPE, Rio de Janeiro, RJ, BrazilUFRJBrazilRio de Janeiro, RJ, BrazilUFRJ, Programa de Engenharia Química, PEQ/COPPE, Rio de Janeiro, RJ, Brazil

F. W. TAVARES

UFRJ, Departamento de Engenharia Química, Escola de Química, Rio de Janeiro, RJ, BrazilUFRJBrazilRio de Janeiro, RJ, BrazilUFRJ, Departamento de Engenharia Química, Escola de Química, Rio de Janeiro, RJ, Brazil

SCIMAGO INSTITUTIONS RANKINGS

UFRJ, Programa de Engenharia Química, PEQ/COPPE, Rio de Janeiro, RJ, BrazilUFRJBrazilRio de Janeiro, RJ, BrazilUFRJ, Programa de Engenharia Química, PEQ/COPPE, Rio de Janeiro, RJ, Brazil

Figures | Tables

Figures (2)
Tables (7)

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Table 1:
Self-diffusion coefficient average absolute deviations, obtained by the fit procedure.

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Table 2:
Lennard-Jones size and energy parameters.

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Table 3:
Self-diffusion coefficients for carbon dioxide at 323 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Etesse et al., 1992).

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Table 4:
Self-diffusion coefficients for ethylene at 298 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Arends et al., 1981).

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Table 5:
Self-diffusion coefficients for ethane at 294 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Schmid et al., 1991).

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Table 6: Self-diffusion coefficients for propane at 294 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Schmid et al., 1991).

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Table 7:
Self-diffusion coefficients for sulfur hexafluoride at 296 K. Comparison of the result obtained with the modified Speedy model and molecular dynamics simulations with experimental data (DeZwaan and Jonas, 1975).

Table 1: Self-diffusion coefficient average absolute deviations, obtained by the fit procedure.

Substance	T(K)	NP⁺	AAD%^*	Data Source
CO₂	323	15	16.8	Etesse et al. (1992)
Ethane	294	5	2.5	Schmid et al. (1991)
Propane	294	5	4.5	Schmid et al. (1991)
Ethylene	298	19	9.9	Arends et al. (1981)
Sulfur hexafluoride	296	6	4.8	DeZwaan and Jonas (1975)

Table 2: Lennard-Jones size and energy parameters.

Substance	s(10^-10m)^*	e /k (K)⁺
Carbon dioxide	3.6003	195.2
Ethane	4.1047	215.7
Propane	4.6398	237.1
Ethylene	3.9671	224.0
Sulfur hexafluoride	4.7808	201.0

Table 3: Self-diffusion coefficients for carbon dioxide at 323 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Etesse et al., 1992).

Pressure	Density	D₁₁ x 10⁸(m²/s)
(bar)	(g/cm³)	Experimental	Modified Speedy model	Molecular dynamics
10.34	0.0289	110.1	106.0	80.7
20.68	0.0579	54.1	52.5	49.3
33.99	0.0880	31.0	34.0	30.9
48.26	0.1088	19.6	27.2	23.8
63.91	0.1790	13.9	15.9	15.9
72.39	0.2020	12.0	13.9	14.3
84.81	0.2376	8.8	11.6	11.4
101.35	0.3454	5.2	7.5	7.6
109.90	0.4640	4.1	5.2	4.8
136.52	0.6700	2.9	3.1	2.8
206.15	0.7950	2.2	2.4	2.2
274.41	0.8530	1.9	2.1	1.9
343.36	0.8960	1.7	1.9	1.7
411.62	0.9286	1.6	1.8	1.6
482.63	0.9570	1.5	1.7	1.5

Table 4: Self-diffusion coefficients for ethylene at 298 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Arends et al., 1981).

Pressure	Density	D₁₁ x 10⁸(m²/s)
(bar)	(g/cm³)	Experimental	Modified Speedy model	Molecular dynamics
58.37	0.1261	11.36	12.40	11.24
62.18	0.1513	9.37	10.00	9.24
65.04	0.1765	7.99	8.29	7.72
67.51	0.2018	6.87	7.00	6.72
70.04	0.2270	6.21	5.99	5.52
73.24	0.2522	5.48	5.18	4.92
77.99	0.2774	4.94	4.51	4.74
85.66	0.3026	4.42	3.96	3.79
98.42	0.3279	3.96	3.48	3.30
119.37	0.3531	3.46	3.06	3.01
152.69	0.3783	3.12	2.70	2.70
203.86	0.4035	2.74	2.38	2.44
279.69	0.4287	2.41	2.09	2.21
388.53	0.4540	2.09	1.83	1.89
540.10	0.4792	1.82	1.60	1.78
745.57	0.5044	1.56	1.38	1.67
1018.81	0.5296	1.34	1.20	1.53
1374.87	0.5548	1.17	1.00	1.23
1828.47	0.5801	0.99	0.85	1.12

Table 5: Self-diffusion coefficients for ethane at 294 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Schmid et al., 1991).

Pressure	Density	D₁₁ x 10⁸(m²/s)
(bar)	(g/cm³)	Experimental	Modified Speedy model	Molecular dynamics
250	0.4320	18.7	19.8	20.9
500	0.4880	14.0	14.0	15.8
1000	0.5300	10.3	10.4	11.1
1500	0.5660	8.6	7.8	10.9
2000	0.5840	7.3	6.6	9.3

Table 6: Self-diffusion coefficients for propane at 294 K. Comparison of the results obtained with the modified Speedy model and molecular dynamics simulations with experimental data (Schmid et al., 1991).

Pressure	Density	D₁₁ x 10⁸(m²/s)
(bar)	(g/cm³)	Experimental	Modified Speedy model	Molecular dynamics
250	0.5420	9.10	9.08	10.67
500	0.5620	7.03	7.57	10.13
1000	0.6100	5.65	5.59	6.91
1500	0.6350	4.58	4.38	5.82
2000	0.6500	3.83	3.46	6.24

Table 7: Self-diffusion coefficients for sulfur hexafluoride at 296 K. Comparison of the result obtained with the modified Speedy model and molecular dynamics simulations with experimental data (DeZwaan and Jonas, 1975).

Pressure	Density	D₁₁ x 10⁹(m²/s)
(bar)	(g/cm³)	Experimental	Modified Speedy model	Molecular dynamics
n.a.	1.3350	9.40	10.16	8.54
84	1.50	7.70	7.52	6.85
161	1.60	6.60	6.16	6.00
311	1.70	5.23	4.95	5.60
574	1.80	3.83	3.89	4.42

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Dense fluid self-diffusion coefficient calculations using perturbation theory and molecular dynamics

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