Structure factor of a hard-core fluid with short-range Yukawa attraction: analytical FMSA theory against Monte Carlo simulations

Melnyk, Roman; Nezbeda, Ivó; Trokhymchuk, Andrij

doi:10.1080/00268976.2016.1177663

Cited by 5 publications

(2 citation statements)

References 28 publications

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“…Miyata and Miyazaki [15] discussed the one component fluids interacting via Lennard-Jones interaction for the study of the temperature derivative of the radial distribution function using the integral equation theory. Melnyk et al [16] found the structure factor of the fluids of the hard core type interacting via short range Yukawa potential using the integral equation theory and the simulation methods. Zhou [17] discussed the fluids with the honeycomb interaction with the integral equation theory.…”

Section: Introductionmentioning

confidence: 99%

Morse potential specific bond volume: a simple formula with applications to dimers and soft–hard slab slider

Al‐Raeei

2022

J. Phys.: Condens. Matter

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Morse potential interaction is an important type of the vibrational potentials, especially, in the quantum mechanics which is used for the describing of general vibrational cases rather than the harmonic one. Morse potential has three fitting parameters, the depth of the Morse interaction, the distance of equilibrium bond and the range parameter which determines the range of the well. The Morse interaction specific bond volume is a three dimensional image of the bond length in its molar case, and this specific volume is the generalisation in three dimensions. In this study, the integral equation theory of the simple fluids has been applied for deriving a novel formula of the specific bond volume for Morse potential based on one of the approaches in the theory and based on the boundary conditions. We find that the specific bond volume of Morse potential depends on the absolute temperature via logarithmic function and square root function, besides, the specific bond volume of Morse potential decreases when the temperature decreases for different values of the molar volume and for different values of the depth of Morse well. In addition to that, the specific bond volume of Morse potential increases when the depth of the well decreases for different temperature values. Also, it is found from the formula which we derive that the specific bond volume of Morse potential increases via linear function with the molar volume of the system for different values of temperatures. We apply the formula of the specific bond volume of Morse potential for finding this specific volume for two molecules of the hydrogen halogens, which are the hydrogen chloride, and hydrogen fluoride. We find that the specific bond volume of the hydrogen chloride is greater than the one of the hydrogen fluoride. Also, we apply the formula for the two simple molecules gases which are the hydrogen molecules, and the nitrogen molecules. Besides, we apply the formula for the slab–slider system in two cases: hard and soft materials, and we concluded that the changes of the specific bond volume of the soft materials is faster than the hard materials. We believe that the formula which is found of the specific bond volume of Morse potential is general and can be applied for multiple materials.

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Section: Introductionmentioning

confidence: 99%

Morse potential specific bond volume: a simple formula with applications to dimers and soft–hard slab slider

Al‐Raeei

2022

J. Phys.: Condens. Matter

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“…The integral equations theory is a significant theory for discussing thermodynamics of multiple spectrum of materials such as soft materials and simple fluids. For instance, Zhou et al (2004) applied the integral equations theory for finding the depletion potential for the colloidal particle, Aguirre-Manzo and González-Mozuelos (2021) discuss the charged colloids with high charges with the salt in suspensions using the theory of the integral equations, Pérez-Molina et al (2021) used the chaotic data with the theory of the integral equations for the estimation of the virial coefficients of the equation of state, Kalyuzhnyi et al (2021) applied the theory of the integral equations with the numerical analysis techniques for the study of the mixtures of colloids, Hashimoto et al (2019) use the theory of the integral equations with the atomic force microscope data for the determination of the number density distribution of colloidal particles on a substrate, Filippov et al (2019) used the theory of the integral equations for the dusty plasma mixtures, Munaò and Saija (2019) studied the hertzian spheres in case of the low temperatures using the theory of the integral equations in addition to the Monte-Carlo simulation, Herrera (2018) found some structural and thermodynamic properties of fluids described by hard sphere and Yukawa potential using the theory of the integral equations, Arauz-Lara showed some application of the integral equations theory to the colloidal fluids, Pizio et al (2011) discussed a model for the simple fluids using the second order of the integral equations theory, Lukšič et al (2011) applied the integral equations theory for the mixtures of the electrolytes and non-charged hard spheres for purpose of the determination of the structural properties and thermodynamics of these mixtures, Fukudome et al (2014) showed a new formula for the direct correlation function for the hard sphere fluids, Wu et al (2014) calculated the static structure factor for the charged spheres using the integral equations theory, Lomba et al (2015) used the three dimensional integral equations approximation for discussing of fluids with confinement and applied in the case of the argon in zeolites, Miyata and Miyazaki (2016) discussed the one component fluids interacting via Lennard-Jones interaction for the study of the temperature derivative of the radial distribution function using the integral equations theory, Melnyk et al (2016) found the structure factor of the fluids of the hard core type interacting via short range Yukawa potential using the integral equations theory and the simulation methods, Al-Raeei (2022a) derived a state equation for London interaction. Also, Al-Raeei (2021) applied the theory for the study of some soft materials, Zhou (2010) discussed the fluids with the honeycomb interaction with the integral equations theory.…”

Section: Introductionmentioning

confidence: 99%

Morse oscillator equation of state: An integral equation theory based with virial expansion and compressibility terms

Al‐Raeei

2022

Heliyon

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Integral-equation theories of fluid phase equilibria in simple fluids

Pellicane

Lee

Caccamo

2020

Fluid Phase Equilibria

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Structure factor of a hard-core fluid with short-range Yukawa attraction: analytical FMSA theory against Monte Carlo simulations

Cited by 5 publications

References 28 publications

Morse potential specific bond volume: a simple formula with applications to dimers and soft–hard slab slider

Morse potential specific bond volume: a simple formula with applications to dimers and soft–hard slab slider

Morse oscillator equation of state: An integral equation theory based with virial expansion and compressibility terms

Integral-equation theories of fluid phase equilibria in simple fluids

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