A data-driven approach to approximate the correlation functions in cluster variation method

Abhishek Kumar Thakur; Rajendra Prasad Gorrey; Vikas Jindal; Krishna Muralidharan

doi:10.1088/1361-651X/ac3a16

A data-driven approach to approximate the correlation functions in cluster variation method

Abhishek Kumar Thakur, Rajendra Prasad Gorrey, Vikas Jindal, Krishna Muralidharan

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

The cluster variation method is one of the thermodynamic models used to calculate phase diagrams considering short range order (SRO). This method predicts the SRO values through internal variables referred to as correlation functions (CFs), accurately up to the cluster chosen in modeling the system. Determination of these CFs at each thermodynamic state of the system requires solving a set of nonlinear equations using numerical methods. In this communication, a neural network model is proposed to predict the values of the CFs. This network is trained for the bcc phase under tetrahedron approximation for both ordering and phase separating systems. The results show that the network can predict the values of the CFs accurately and thereby Helmholtz energy and the phase diagram with significantly less computational burden than that of conventional methods used.

Original language	English (US)
Article number	015001
Journal	Modelling and Simulation in Materials Science and Engineering
Volume	30
Issue number	1
DOIs	https://doi.org/10.1088/1361-651X/ac3a16
State	Published - Jan 2022

Keywords

cluster variation method
correlation functions
neural network model
short range order
tetrahedron approximation

ASJC Scopus subject areas

Modeling and Simulation
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Computer Science Applications

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10.1088/1361-651X/ac3a16

Cite this

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abstract = "The cluster variation method is one of the thermodynamic models used to calculate phase diagrams considering short range order (SRO). This method predicts the SRO values through internal variables referred to as correlation functions (CFs), accurately up to the cluster chosen in modeling the system. Determination of these CFs at each thermodynamic state of the system requires solving a set of nonlinear equations using numerical methods. In this communication, a neural network model is proposed to predict the values of the CFs. This network is trained for the bcc phase under tetrahedron approximation for both ordering and phase separating systems. The results show that the network can predict the values of the CFs accurately and thereby Helmholtz energy and the phase diagram with significantly less computational burden than that of conventional methods used.",

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AU - Thakur, Abhishek Kumar

AU - Gorrey, Rajendra Prasad

AU - Jindal, Vikas

AU - Muralidharan, Krishna

PY - 2022/1

Y1 - 2022/1

N2 - The cluster variation method is one of the thermodynamic models used to calculate phase diagrams considering short range order (SRO). This method predicts the SRO values through internal variables referred to as correlation functions (CFs), accurately up to the cluster chosen in modeling the system. Determination of these CFs at each thermodynamic state of the system requires solving a set of nonlinear equations using numerical methods. In this communication, a neural network model is proposed to predict the values of the CFs. This network is trained for the bcc phase under tetrahedron approximation for both ordering and phase separating systems. The results show that the network can predict the values of the CFs accurately and thereby Helmholtz energy and the phase diagram with significantly less computational burden than that of conventional methods used.

AB - The cluster variation method is one of the thermodynamic models used to calculate phase diagrams considering short range order (SRO). This method predicts the SRO values through internal variables referred to as correlation functions (CFs), accurately up to the cluster chosen in modeling the system. Determination of these CFs at each thermodynamic state of the system requires solving a set of nonlinear equations using numerical methods. In this communication, a neural network model is proposed to predict the values of the CFs. This network is trained for the bcc phase under tetrahedron approximation for both ordering and phase separating systems. The results show that the network can predict the values of the CFs accurately and thereby Helmholtz energy and the phase diagram with significantly less computational burden than that of conventional methods used.

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A data-driven approach to approximate the correlation functions in cluster variation method

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