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On the decay of the pair correlation function and the line of vanishing excess isothermal compressibility in simple fluids

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On the decay of the pair correlation function and the line of vanishing excess isothermal compressibility in simple fluids. / Stopper, Daniel; Hansen-Goos, Hendrik; Roth, Roland; Evans, Robert.

In: Journal of Chemical Physics, Vol. 151, No. 1, 014501, 07.07.2019.

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Stopper, Daniel ; Hansen-Goos, Hendrik ; Roth, Roland ; Evans, Robert. / On the decay of the pair correlation function and the line of vanishing excess isothermal compressibility in simple fluids. In: Journal of Chemical Physics. 2019 ; Vol. 151, No. 1.

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@article{0d770e51436e4fb39750d39a0ea25578,
title = "On the decay of the pair correlation function and the line of vanishing excess isothermal compressibility in simple fluids",
abstract = "We revisit the competition between attractive and repulsive interparticle forces in simple fluids and how this governs and connects the macroscopic phase behavior and structural properties, as manifested in pair correlation functions. We focus on the asymptotic decay of the total correlation function h(r) which is, in turn, controlled by the form of the pair direct correlation function c(r). The decay of rh(r) to zero can be exponential (monotonic) if attraction dominates repulsion and exponentially damped oscillatory otherwise. The Fisher-Widom (FW) line separates the phase diagram into two regions characterized by the two different types of asymptotic decays. We show that there is a new and physically intuitive thermodynamic criterion which approximates well the actual FW line. This new criterion defines a line where the isothermal compressibility takes its ideal gas value χT=χTid. We test our hypothesis by considering four commonly used models for simple fluids. In all cases, the new criterion yields a line in the phase diagram that is close to the actual FW line for the thermodynamic state points that are most relevant. We also investigate (Widom) lines of maximal correlation length, emphasizing the importance of distinguishing between the true and Ornstein-Zernike correlation lengths.",
author = "Daniel Stopper and Hendrik Hansen-Goos and Roland Roth and Robert Evans",
year = "2019",
month = "7",
day = "7",
doi = "10.1063/1.5110044",
language = "English",
volume = "151",
journal = "Journal of Chemical Physics",
issn = "0021-9606",
publisher = "American Institute of Physics (AIP)",
number = "1",

}

RIS - suitable for import to EndNote

TY - JOUR

T1 - On the decay of the pair correlation function and the line of vanishing excess isothermal compressibility in simple fluids

AU - Stopper, Daniel

AU - Hansen-Goos, Hendrik

AU - Roth, Roland

AU - Evans, Robert

PY - 2019/7/7

Y1 - 2019/7/7

N2 - We revisit the competition between attractive and repulsive interparticle forces in simple fluids and how this governs and connects the macroscopic phase behavior and structural properties, as manifested in pair correlation functions. We focus on the asymptotic decay of the total correlation function h(r) which is, in turn, controlled by the form of the pair direct correlation function c(r). The decay of rh(r) to zero can be exponential (monotonic) if attraction dominates repulsion and exponentially damped oscillatory otherwise. The Fisher-Widom (FW) line separates the phase diagram into two regions characterized by the two different types of asymptotic decays. We show that there is a new and physically intuitive thermodynamic criterion which approximates well the actual FW line. This new criterion defines a line where the isothermal compressibility takes its ideal gas value χT=χTid. We test our hypothesis by considering four commonly used models for simple fluids. In all cases, the new criterion yields a line in the phase diagram that is close to the actual FW line for the thermodynamic state points that are most relevant. We also investigate (Widom) lines of maximal correlation length, emphasizing the importance of distinguishing between the true and Ornstein-Zernike correlation lengths.

AB - We revisit the competition between attractive and repulsive interparticle forces in simple fluids and how this governs and connects the macroscopic phase behavior and structural properties, as manifested in pair correlation functions. We focus on the asymptotic decay of the total correlation function h(r) which is, in turn, controlled by the form of the pair direct correlation function c(r). The decay of rh(r) to zero can be exponential (monotonic) if attraction dominates repulsion and exponentially damped oscillatory otherwise. The Fisher-Widom (FW) line separates the phase diagram into two regions characterized by the two different types of asymptotic decays. We show that there is a new and physically intuitive thermodynamic criterion which approximates well the actual FW line. This new criterion defines a line where the isothermal compressibility takes its ideal gas value χT=χTid. We test our hypothesis by considering four commonly used models for simple fluids. In all cases, the new criterion yields a line in the phase diagram that is close to the actual FW line for the thermodynamic state points that are most relevant. We also investigate (Widom) lines of maximal correlation length, emphasizing the importance of distinguishing between the true and Ornstein-Zernike correlation lengths.

UR - http://www.scopus.com/inward/record.url?scp=85068456879&partnerID=8YFLogxK

U2 - 10.1063/1.5110044

DO - 10.1063/1.5110044

M3 - Article

C2 - 31272162

AN - SCOPUS:85068456879

VL - 151

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

SN - 0021-9606

IS - 1

M1 - 014501

ER -