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Molecular Physics
An International Journal at the Interface Between Chemistry and Physics
Volume 48, 1983 - Issue 4
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Original Articles

Application of perturbation theory to the calculation of the dielectric constant of a dipolar hard sphere fluid

A. Tani IBM Research Laboratory, San Jose, California, 95193, U.S.A.; Instituto di Chimica Fisica, Universita di Pisa, via Risorgimento 35, 56100, Pisa, Italy
,
D. Henderson IBM Research Laboratory, San Jose, California, 95193, U.S.A.
,
J.A. Barker IBM Research Laboratory, San Jose, California, 95193, U.S.A.
&
C.E. Hecht Department of Chemistry, City University of New York, Hunter College, New York, New York, 10021, U.S.A.View further author information
Pages 863-869 | Received 23 Aug 1982, Accepted 04 Oct 1982, Published online: 22 Aug 2006

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. (2008) Erratum. Molecular Physics 106:8, pages 1093-1106.
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András Gábor & István Szalai. (2008) Electric field dependence of phase equilibria of binary Stockmayer fluid mixtures. Molecular Physics 106:6, pages 801-812.
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Attila Malasics, Dezső Boda & Mónika Valiskó. (2006) Monte Carlo simulation and renormalized perturbation theory study of the dielectric properties of mixtures of polarizable hard spheres and polarizable dipolar hard spheres. Molecular Physics 104:22-24, pages 3821-3830.
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MÓNIKA VALISKÓ, DEZSŐ BODA, JÁNOS LISZI & ISTVÁN SZALAI. (2003) A systematic Monte Carlo simulation and renormalized perturbation theoretical study of the dielectric constant of the polarizable Stockmayer fluid. Molecular Physics 101:14, pages 2309-2313.
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MÓNIKA VALISKÓ, DEZSÖ BODA, JÁNOS LISZI & ISTVÁN SZALAI. (2002) The dielectric constant of polarizable fluids from the renormalized perturbation theory. Molecular Physics 100:20, pages 3239-3243.
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GEORGE JACKSON. (1998) John Adair Barker 24 March 1925–27 October 1995. Molecular Physics 95:3, pages 675-680.
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Dezső Boda, Jochen Winkelmann, János Liszi & István Szalai. (1996) Vapour-liquid equilibrium of Stockmayer fluids in applied field. Molecular Physics 87:3, pages 601-624.
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Chris Joslin & Saul Goldman. (1993) The third dielectric and pressure virial coefficients of dipolar hard sphere fluids. Molecular Physics 79:3, pages 499-514.
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Saul Goldman. (1990) Determination of static dielectric constant-temperature-density surfaces of a Stockmayer fluid by perturbation theory. Molecular Physics 71:3, pages 491-507.
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V. Russier & D. Henderson. (1988) Size effect on the dielectric constant of the dipolar hard sphere fluid. Molecular Physics 64:2, pages 261-278.
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G.S. Rushbrooke & R.G. Shrubsall. (1985) On the third dielectric virial coefficient for dipolar hard spheres. Molecular Physics 55:3, pages 599-610.
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J.P. Badiali & M.E. Boudh-Hir. (1984) Structure of the dipolar hard sphere fluid near a hard wall. Molecular Physics 53:6, pages 1399-1410.
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Articles from other publishers (47)

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Lisa Rueben, Johannes Schilling, Philipp Rehner, Simon Müller, Timm Esper, André Bardow & Joachim Gross. (2023) Predicting the Relative Static Permittivity: a Group Contribution Method Based on Perturbation Theory. Journal of Chemical & Engineering Data 69:2, pages 414-426.
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Dmitry V. Matyushov. (2022) Multiparticle orientational correlations are responsible for the nonlinear dielectric effect: Analysis of temperature-dependent measurements for glycerol. The Journal of Chemical Physics 157:16.
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S. Kournopoulos, A. J. Haslam, G. Jackson, A. Galindo & M. Schoen. (2022) Molecular theory of the static dielectric constant of dipolar fluids. The Journal of Chemical Physics 156:15.
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Lisa Neumaier, Johannes Schilling, André Bardow & Joachim Gross. (2022) Dielectric constant of mixed solvents based on perturbation theory. Fluid Phase Equilibria 555, pages 113346.
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Pierre-Michel Déjardin. (2022) Kinetic Yvon-Born-Green theory of the linear dielectric constant and complex permittivity of isotropic polar fluids. Physical Review E 105:2.
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Maximilian Kohns, Joshua Marx & Kai Langenbach. (2021) Critical assessment of perturbation theories for the relative permittivity of dipolar model fluids. Chemical Engineering Science 245, pages 116875.
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Maximilian Kohns, Joshua Marx & Kai Langenbach. (2020) Relative Permittivity of Stockmayer-Type Model Fluids from MD Simulations and COFFEE. Journal of Chemical & Engineering Data 65:12, pages 5891-5896.
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Marc Theiss & Joachim Gross. (2020) Perturbation approaches for describing dipolar fluids and electrolyte solutions. The Journal of Chemical Physics 153:4, pages 044102.
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Sándor Nagy. (2018) The magnetization of dense aggregated dipolar fluids. Analecta Technica Szegedinensia 12:2, pages 1-12.
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Bilin Zhuang & Zhen-Gang Wang. (2018) Statistical field theory for polar fluids. The Journal of Chemical Physics 149:12.
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Marc Theiss & Joachim Gross. (2018) A third and fourth order perturbation theory for dipolar hard spheres. The Journal of Chemical Physics 149:4.
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Ricardo Palomar & Gemma Sesé. (2018) Free energy and entropy of a dipolar liquid by computer simulations. The Journal of Chemical Physics 148:8.
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Florian Drunsel & Joachim Gross. (2016) Theory of model electrolyte solutions: Assessing the short- and long-ranged contributions by molecular simulations. Fluid Phase Equilibria 430, pages 195-206.
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I. Szalai, S. Nagy & S. Dietrich. (2015) Linear and nonlinear magnetic properties of ferrofluids. Physical Review E 92:4.
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Lewis E. Johnson, Stephanie J. Benight, Robin Barnes & Bruce H. Robinson. (2015) Dielectric and Phase Behavior of Dipolar Spheroids. The Journal of Physical Chemistry B 119:16, pages 5240-5250.
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S. Lamperski & R. Górniak. (2010) Inverse grand-canonical Monte Carlo investigation of the activity coefficient of polar fluids. Fluid Phase Equilibria 295:2, pages 255-263.
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Lewis E. Johnson, Robin Barnes, Thomas W. Draxler, Bruce E. Eichinger & Bruce H. Robinson. (2010) Dielectric Constants of Simple Liquids: Stockmayer and Ellipsoidal Fluids. The Journal of Physical Chemistry B 114:25, pages 8431-8440.
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Daniel R. Martin & Dmitry V. Matyushov. (2008) Microscopic fields in liquid dielectrics. The Journal of Chemical Physics 129:17.
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MOHAMMAD KAMALVAND, TAHMINEH (EZZAT) KESHAVARZI & G. ALI MANSOORI. (2011) BEHAVIOR OF THE CONFINED HARD-SPHERE FLUID WITHIN NANOSLITS: A FUNDAMENTAL-MEASURE DENSITY-FUNCTIONAL THEORY STUDY. International Journal of Nanoscience 07:04n05, pages 245-253.
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Sorin Bastea & Laurence E. Fried. (2008) Exp6-polar thermodynamics of dense supercritical water. The Journal of Chemical Physics 128:17.
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Konstantin I. Morozov. (2007) The dielectric virial expansion and the models of dipolar hard-sphere fluid. The Journal of Chemical Physics 126:19.
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Tamás Kristóf & István Szalai. (2005) Magnetic properties in monolayers of a model polydisperse ferrofluid. Physical Review E 72:4.
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J.-J. Weis. (2005) The ferroelectric transition of dipolar hard spheres. The Journal of Chemical Physics 123:4.
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Mónika Valiskó & Dezső Boda. (2005) Relative Permittivity of Polar Liquids. Comparison of Theory, Experiment, and Simulation. The Journal of Physical Chemistry B 109:13, pages 6355-6365.
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B Huke & M Lücke. (2004) Magnetic properties of colloidal suspensions of interacting magnetic particles. Reports on Progress in Physics 67:10, pages 1731-1768.
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Dmitry V. Matyushov. (2004) Solvent reorganization energy of electron-transfer reactions in polar solvents. The Journal of Chemical Physics 120:16, pages 7532-7556.
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G A van Ewijk, G J Vroege & A P Philipse. (2002) Susceptibility measurements on a fractionated aggregate-free ferrofluid. Journal of Physics: Condensed Matter 14:19, pages 4915-4925.
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Anatoli Milischuk & Dmitry V. Matyushov. (2001) Dipole Solvation:  Nonlinear Effects, Density Reorganization, and the Breakdown of the Onsager Saturation Limit. The Journal of Physical Chemistry A 106:10, pages 2146-2157.
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Fernando O. Raineri & George Stell. (2001) Dielectrically Nontrivial Closures for the RISM Integral Equation. The Journal of Physical Chemistry B 105:47, pages 11880-11892.
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Alexey O. Ivanov & Olga B. Kuznetsova. (2001) Magnetic properties of dense ferrofluids: An influence of interparticle correlations. Physical Review E 64:4.
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István Szalai, Kwong-Yu Chan & Douglas Henderson. (2000) Comment on “Algebraic perturbation theory for polar fluids: A model for the dielectric constant”. Physical Review E 62:6, pages 8846-8850.
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István Szalai, Douglas Henderson, Dezsö Boda & Kwong-Yu Chan. (1999) Thermodynamics and structural properties of the dipolar Yukawa fluid. The Journal of Chemical Physics 111:1, pages 337-344.
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Dmitry V. Matyushov & Branka M. Ladanyi. (1999) A perturbation theory and simulations of the dipole solvation thermodynamics: Dipolar hard spheres. The Journal of Chemical Physics 110:2, pages 994-1009.
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Dmitry V. Matyushov & Branka M. Ladanyi. (1997) Nonlinear effects in dipole solvation. I. Thermodynamics. The Journal of Chemical Physics 107:5, pages 1362-1374.
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Dezső Boda, Balázs Kalmár, János Liszi & István Szalai. (1996) Fluid–fluid equilibrium of a mixture of non-polar and dipolar hard spheres in an applied field. J. Chem. Soc., Faraday Trans. 92:15, pages 2709-2714.
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Saul Goldman & Chris Joslin. (2010) Calculation of the Static Dielectric Constant of Multipolar Mixtures by Perturbation Theory. An Application to Supercritical Water‐Benzene Mixtures. Berichte der Bunsengesellschaft für physikalische Chemie 99:2, pages 204-210.
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Dezsö Boda, István Szalai & János Liszi. (1995) Influence of static electric field on the vapour–liquid coexistence of dipolar soft-sphere fluids. J. Chem. Soc., Faraday Trans. 91:5, pages 889-894.
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Saul Goldman & Chris Joslin. (1993) The static dielectric constant of SPC and TIP4P water by perturbation theory. The Journal of Chemical Physics 99:4, pages 3021-3029.
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John Eggebrecht & Pelin Ozler. (1993) Multipolar electrolyte solution models. IV. Thermodynamic perturbation theory. The Journal of Chemical Physics 98:2, pages 1552-1565.
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Günther H. Peters & John Eggebrecht. (1993) Multipolar electrolyte solution models. III. Free energy of the charged and dipolar hard sphere mixture. The Journal of Chemical Physics 98:2, pages 1546-1551.
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W. W. Hill, S. Rosenzweig & E. U. Franck. (2010) The Static Dielectric Constant of Methyl Cyanide to 350°C and 2000 bar. Berichte der Bunsengesellschaft für physikalische Chemie 94:5, pages 564-568.
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E. U. Franck, S. Rosenzweig & M. Christoforakos. (2010) Calculation of the Dielectric Constant of Water to 1000°C and Very High Pressures. Berichte der Bunsengesellschaft für physikalische Chemie 94:2, pages 199-203.
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Pil H. Lee & Branka M. Ladanyi. (1989) Structural and dielectric properties of dipolar hard sphere mixtures: Reference hypernetted chain and pertubation theory results. The Journal of Chemical Physics 91:11, pages 7063-7074.
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Pil H. Lee & Branka M. Ladanyi. (1987) Structural and dielectric properties of dipolar hard sphere mixtures. The Journal of Chemical Physics 87:7, pages 4093-4099.
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P. H. Fries & G. N. Patey. (1985) The solution of the hypernetted-chain approximation for fluids of nonspherical particles. A general method with application to dipolar hard spheres. The Journal of Chemical Physics 82:1, pages 429-440.
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