Origin of the failed ensemble average rule for the band gaps of disordered nonisovalent semiconductor alloys

Jie Ma; Hui Xiong Deng; Jun Wei Luo; Su Huai Wei

doi:10.1103/PhysRevB.90.115201

Origin of the failed ensemble average rule for the band gaps of disordered nonisovalent semiconductor alloys

Jie Ma, Hui Xiong Deng, Jun Wei Luo, Su Huai Wei

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

15 Citations (Scopus)

Abstract

Recent calculations show that the band gaps of the nonisovalent random alloys such as Zn0.5Sn0.5P are much smaller than those of their ordered phases; that is, the band gap of the random alloy is not the ensemble averaged value of the ordered structures, in contrast to the trend observed in most isovalent semiconductor alloys and predicted by the cluster expansion theory. We show that this abnormal behavior is caused by the strong wave-function localization of the band-edge states in the nonisovalent alloys. Moreover, we show that although the disordered phase of the isovalent alloys is similar to the random phase, for the nonisovalent alloy, the disordered phase deviates significantly from the random phase and the fully random phase is not achievable under the equilibrium growth conditions.

Original language	English
Article number	115201
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	90
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevB.90.115201
Publication status	Published - 2 Sept 2014
Externally published	Yes

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title = "Origin of the failed ensemble average rule for the band gaps of disordered nonisovalent semiconductor alloys",

abstract = "Recent calculations show that the band gaps of the nonisovalent random alloys such as Zn0.5Sn0.5P are much smaller than those of their ordered phases; that is, the band gap of the random alloy is not the ensemble averaged value of the ordered structures, in contrast to the trend observed in most isovalent semiconductor alloys and predicted by the cluster expansion theory. We show that this abnormal behavior is caused by the strong wave-function localization of the band-edge states in the nonisovalent alloys. Moreover, we show that although the disordered phase of the isovalent alloys is similar to the random phase, for the nonisovalent alloy, the disordered phase deviates significantly from the random phase and the fully random phase is not achievable under the equilibrium growth conditions.",

author = "Jie Ma and Deng, \{Hui Xiong\} and Luo, \{Jun Wei\} and Wei, \{Su Huai\}",

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T1 - Origin of the failed ensemble average rule for the band gaps of disordered nonisovalent semiconductor alloys

AU - Ma, Jie

AU - Deng, Hui Xiong

AU - Luo, Jun Wei

AU - Wei, Su Huai

PY - 2014/9/2

Y1 - 2014/9/2

N2 - Recent calculations show that the band gaps of the nonisovalent random alloys such as Zn0.5Sn0.5P are much smaller than those of their ordered phases; that is, the band gap of the random alloy is not the ensemble averaged value of the ordered structures, in contrast to the trend observed in most isovalent semiconductor alloys and predicted by the cluster expansion theory. We show that this abnormal behavior is caused by the strong wave-function localization of the band-edge states in the nonisovalent alloys. Moreover, we show that although the disordered phase of the isovalent alloys is similar to the random phase, for the nonisovalent alloy, the disordered phase deviates significantly from the random phase and the fully random phase is not achievable under the equilibrium growth conditions.

AB - Recent calculations show that the band gaps of the nonisovalent random alloys such as Zn0.5Sn0.5P are much smaller than those of their ordered phases; that is, the band gap of the random alloy is not the ensemble averaged value of the ordered structures, in contrast to the trend observed in most isovalent semiconductor alloys and predicted by the cluster expansion theory. We show that this abnormal behavior is caused by the strong wave-function localization of the band-edge states in the nonisovalent alloys. Moreover, we show that although the disordered phase of the isovalent alloys is similar to the random phase, for the nonisovalent alloy, the disordered phase deviates significantly from the random phase and the fully random phase is not achievable under the equilibrium growth conditions.

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JF - Physical Review B - Condensed Matter and Materials Physics

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Origin of the failed ensemble average rule for the band gaps of disordered nonisovalent semiconductor alloys

Abstract

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