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Main Authors: Liang, Han-Pu, Li, Chuan-Nan, Tang, Xin-Ru, Xu, Xun, Qiu, Chen, Huang, Qiu-Shi, Wei, Su-Huai
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.10259
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author Liang, Han-Pu
Li, Chuan-Nan
Tang, Xin-Ru
Xu, Xun
Qiu, Chen
Huang, Qiu-Shi
Wei, Su-Huai
author_facet Liang, Han-Pu
Li, Chuan-Nan
Tang, Xin-Ru
Xu, Xun
Qiu, Chen
Huang, Qiu-Shi
Wei, Su-Huai
contents Alloying compound AX with another compound BX is widely used to tune material properties. For disordered alloys, due to the lack of periodicity, it has been challenging to calculate and study their material properties. Special quasi-random structure (SQS) method has been developed and widely used to treat this issue by matching averaged atomic correlation functions to those of ideal random alloys, enabling accurate predictions of macroscopic material properties such as total energy and volume. However, in AxB1-x alloys, statistically allowed local concentration fluctuations can give rise to defect-like minority configurations, such as bulk-like AX or BX regions in the extreme, which could strongly affect calculation of some of the material properties such as semiconductor bandgap, if it is not defined properly, leading to significant discrepancies between theory and experiment. In this work, taking the bandgap as an example, we demonstrate that the calculated alloy bandgap can be significantly underestimated in standard SQS calculations when the SQS cell size is increased to improve the structural model and the bandgap is defined conventionally as the energy difference between the lowest unoccupied state and the highest occupied state, because the rare event motifs can lead to wavefunction localization and become the dominant factor in determining the "bandgap", contrary to experiment. To be consistent with experiment, we show that the bandgap of the alloy should be extracted from the majority configurations using a density-of-states fitting (DOSF) method. This DOSF approach resolves the long-standing issue of calculating electronic structure of disordered semiconductor alloys. Similar approaches should also be developed to treat material properties that depends on localized alloy wavefunctions.
format Preprint
id arxiv_https___arxiv_org_abs_2511_10259
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Effect of Concentration Fluctuations on Material Properties of Disordered Alloys
Liang, Han-Pu
Li, Chuan-Nan
Tang, Xin-Ru
Xu, Xun
Qiu, Chen
Huang, Qiu-Shi
Wei, Su-Huai
Materials Science
Computational Physics
Alloying compound AX with another compound BX is widely used to tune material properties. For disordered alloys, due to the lack of periodicity, it has been challenging to calculate and study their material properties. Special quasi-random structure (SQS) method has been developed and widely used to treat this issue by matching averaged atomic correlation functions to those of ideal random alloys, enabling accurate predictions of macroscopic material properties such as total energy and volume. However, in AxB1-x alloys, statistically allowed local concentration fluctuations can give rise to defect-like minority configurations, such as bulk-like AX or BX regions in the extreme, which could strongly affect calculation of some of the material properties such as semiconductor bandgap, if it is not defined properly, leading to significant discrepancies between theory and experiment. In this work, taking the bandgap as an example, we demonstrate that the calculated alloy bandgap can be significantly underestimated in standard SQS calculations when the SQS cell size is increased to improve the structural model and the bandgap is defined conventionally as the energy difference between the lowest unoccupied state and the highest occupied state, because the rare event motifs can lead to wavefunction localization and become the dominant factor in determining the "bandgap", contrary to experiment. To be consistent with experiment, we show that the bandgap of the alloy should be extracted from the majority configurations using a density-of-states fitting (DOSF) method. This DOSF approach resolves the long-standing issue of calculating electronic structure of disordered semiconductor alloys. Similar approaches should also be developed to treat material properties that depends on localized alloy wavefunctions.
title Effect of Concentration Fluctuations on Material Properties of Disordered Alloys
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2511.10259