Optimization Methodology of Empirical Electronic Theory by Employing Statistical Model

Donghu Yang; Qunbo Fan; Fuchi Wang; Lu Wang; Tiejian Su

doi:10.15918/j.jbit1004-0579.18122

Optimization Methodology of Empirical Electronic Theory by Employing Statistical Model

Donghu Yang, Qunbo Fan^*, Fuchi Wang, Lu Wang, Tiejian Su

^*Corresponding author for this work

School of Material Science and Engineering

Beijing Institute of Technology

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

Abstract

An optimization methodology of empirical electronic theory (EET) for solids and molecules has been developed by employing a statistical model in this study. The current paper calculates the hybridization states of different atoms in some crystal structures and succeeds in predicting valence states of atoms. The prediction of γ-Fe hybridization states based on statistics is found to be in reasonable agreement with early measurements. Through calculating Cr alloy austenite and Cr alloy martensite, the statistical results proved stable for each atom, and it is found that the valence electron structure of an atom depends on its element type and location in the crystal cell; finally, wear resistant steel with 1 wt% C is designed by using a statistical model which is consistent with traditional empirical design.

Original language	English
Pages (from-to)	426-432
Number of pages	7
Journal	Journal of Beijing Institute of Technology (English Edition)
Volume	27
Issue number	3
DOIs	https://doi.org/10.15918/j.jbit1004-0579.18122
Publication status	Published - 1 Sept 2018

Keywords

Empirical electronic theory (EET)
Material design
Statistical model
Valence electron structure (VES)

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10.15918/j.jbit1004-0579.18122

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title = "Optimization Methodology of Empirical Electronic Theory by Employing Statistical Model",

abstract = "An optimization methodology of empirical electronic theory (EET) for solids and molecules has been developed by employing a statistical model in this study. The current paper calculates the hybridization states of different atoms in some crystal structures and succeeds in predicting valence states of atoms. The prediction of γ-Fe hybridization states based on statistics is found to be in reasonable agreement with early measurements. Through calculating Cr alloy austenite and Cr alloy martensite, the statistical results proved stable for each atom, and it is found that the valence electron structure of an atom depends on its element type and location in the crystal cell; finally, wear resistant steel with 1 wt% C is designed by using a statistical model which is consistent with traditional empirical design.",

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T1 - Optimization Methodology of Empirical Electronic Theory by Employing Statistical Model

AU - Yang, Donghu

AU - Fan, Qunbo

AU - Wang, Fuchi

AU - Wang, Lu

AU - Su, Tiejian

PY - 2018/9/1

Y1 - 2018/9/1

N2 - An optimization methodology of empirical electronic theory (EET) for solids and molecules has been developed by employing a statistical model in this study. The current paper calculates the hybridization states of different atoms in some crystal structures and succeeds in predicting valence states of atoms. The prediction of γ-Fe hybridization states based on statistics is found to be in reasonable agreement with early measurements. Through calculating Cr alloy austenite and Cr alloy martensite, the statistical results proved stable for each atom, and it is found that the valence electron structure of an atom depends on its element type and location in the crystal cell; finally, wear resistant steel with 1 wt% C is designed by using a statistical model which is consistent with traditional empirical design.

AB - An optimization methodology of empirical electronic theory (EET) for solids and molecules has been developed by employing a statistical model in this study. The current paper calculates the hybridization states of different atoms in some crystal structures and succeeds in predicting valence states of atoms. The prediction of γ-Fe hybridization states based on statistics is found to be in reasonable agreement with early measurements. Through calculating Cr alloy austenite and Cr alloy martensite, the statistical results proved stable for each atom, and it is found that the valence electron structure of an atom depends on its element type and location in the crystal cell; finally, wear resistant steel with 1 wt% C is designed by using a statistical model which is consistent with traditional empirical design.

KW - Empirical electronic theory (EET)

KW - Material design

KW - Statistical model

KW - Valence electron structure (VES)

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Optimization Methodology of Empirical Electronic Theory by Employing Statistical Model

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