Is there a one-to-one correspondence between interparticle interactions and physical properties of liquid?

In this study, we present the original method for reconstructing the potential of interparticle interaction from statistically averaged structural data, namely, the radial distribution function of particles in many-particle system. This method belongs to a family of machine learning methods and is i...

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Veröffentlicht in:	arXiv.org 2022-11
Hauptverfasser:	Mokshin, Anatolii V, Khabibullin, Roman A
Format:	Artikel
Sprache:	eng
Schlagworte:	Diffusion coefficient Distribution functions Evolutionary algorithms Evolutionary computation Machine learning Particles Physical properties Physics - Chemical Physics Physics - Computational Physics Physics - Disordered Systems and Neural Networks Physics - Soft Condensed Matter Physics - Statistical Mechanics Radial distribution Self diffusion Structure factor Thermodynamics Transport properties
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creator	Mokshin, Anatolii V Khabibullin, Roman A
description	In this study, we present the original method for reconstructing the potential of interparticle interaction from statistically averaged structural data, namely, the radial distribution function of particles in many-particle system. This method belongs to a family of machine learning methods and is implemented through the differential evolution algorithm. As demonstrated for the case of the Lennard-Jones liquid taken as an example, there is no one-to-one correspondence between structure and potential of interparticle interaction of a many-particle disordered system at a certain thermodynamic state. Namely, a whole family of the Mie potentials determined by two parameters $p_{ 1 }$ and $p_{ 2 }$ related to each other according to a certain rule can reproduce properly a unique structure of the Lennard-Jones liquid at a given thermodynamic state. It is noteworthy that this family of the potentials quite correctly reproduces for the Lennard-Jones liquid the transport properties (in particular, the self-diffusion coefficient) over a temperature range as well as the dynamic structure factor, which is one of the key characteristics of the collective dynamics of particles.
doi_str_mv	10.48550/arxiv.2211.10559
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subjects	Diffusion coefficient Distribution functions Evolutionary algorithms Evolutionary computation Machine learning Particles Physical properties Physics - Chemical Physics Physics - Computational Physics Physics - Disordered Systems and Neural Networks Physics - Soft Condensed Matter Physics - Statistical Mechanics Radial distribution Self diffusion Structure factor Thermodynamics Transport properties
title	Is there a one-to-one correspondence between interparticle interactions and physical properties of liquid?
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