Thermodynamics of the Stockmayer fluid in an applied field / Elfimova Ekaterina A.,Ivanov Alexey O.,Sindt Julien O.,Camp Philip J. // MOLECULAR PHYSICS. - 2015. - V. 113, l. 23. - P. 3717-3728.

ISSN/EISSN:
0026-8976 / 1362-3028
Type:
Article
Abstract:
The thermodynamic properties of the Stockmayer fluid in an applied field are studied using theory and computer simulation. Theoretical expressions for the second and third virial coefficients are obtained in terms of the dipolar coupling constant (, measuring the strength of dipolar interactions as compared to thermal energy) and dipole-field interaction energy (, being proportional to the applied field strength). These expressions are tested against numerical results obtained by Mayer sampling calculations. The expression for the second virial coefficient contains terms up to (4), and is found to be accurate over realistic ranges of dipole moment and temperature, and over the entire range of the applied field strength (from zero to infinity). The corresponding expression for the third virial coefficient is truncated at (3), and is not very accurate: higher order terms are very difficult to calculate. The virial coefficients are incorporated in to a thermodynamic theory based on a logarithmic representation of the Helmholtz free energy. This theory is designed to retain the input virial coefficients, and account for some higher order terms in the sense of a resummation. The compressibility factor is obtained from the theory and compared to results from molecular dynamics simulations with a typical value = 1. Despite the mathematical approximations of the virial coefficients, the theory captures the effects of the applied field very well. Finally, the vapour-liquid critical parameters are determined from the theory, and compared to published simulation results; the agreement between the theory and simulations is good.
Author keywords:
Stockmayer fluid; applied field; theory; simulation DIPOLAR HARD-SPHERES; EQUATION-OF-STATE; VIRIAL-COEFFICIENTS; PERTURBATION-THEORY; POLAR GASES; COMPUTER-SIMULATIONS; CRITICAL-TEMPERATURE; PHASE-BEHAVIOR; LIQUID; ORDER
DOI:
10.1080/00268976.2015.1058979
Web of Science ID:
ISI:000365645800009
Соавторы в МНС:
Другие поля
Поле Значение
Month DEC 2
Publisher TAYLOR \& FRANCIS LTD
Address 4 PARK SQUARE, MILTON PARK, ABINGDON OX14 4RN, OXON, ENGLAND
Language English
EISSN 1362-3028
Keywords-Plus DIPOLAR HARD-SPHERES; EQUATION-OF-STATE; VIRIAL-COEFFICIENTS; PERTURBATION-THEORY; POLAR GASES; COMPUTER-SIMULATIONS; CRITICAL-TEMPERATURE; PHASE-BEHAVIOR; LIQUID; ORDER
Research-Areas Chemistry; Physics
Web-of-Science-Categories Chemistry, Physical; Physics, Atomic, Molecular \& Chemical
Author-Email philip.camp@ed.ac.uk
ResearcherID-Numbers Ivanov, Alexey/E-4442-2011 Elfimova, Ekaterina/P-5003-2016
ORCID-Numbers Ivanov, Alexey/0000-0001-8239-4039 Elfimova, Ekaterian/0000-0002-8941-8184 Camp, Philip/0000-0002-7901-1364
Funding-Acknowledgement Ministry of Education and Science of the Russian Federation {[}3.12.2014/K, 02.A03.21.0006]; Engineering and Physical Sciences Research Council (UK)
Funding-Text Ekaterina A. Elfimovaand Alexey O. Ivanov gratefully acknowledge research funding from the Ministry of Education and Science of the Russian Federation {[}agreement no. 3.12.2014/K, contract no. 02.A03.21.0006]. Julien O. Sindt was supported by the Engineering and Physical Sciences Research Council (UK) through the provision of a studentship.
Number-of-Cited-References 60
Usage-Count-Last-180-days 1
Usage-Count-Since-2013 5
Journal-ISO Mol. Phys.
Doc-Delivery-Number CX4CM