Theoretical analysis of unstable two-phase region and microscopic structure in wurtzite and zinc-blende InGaN using modified valence force field model

Takayama, Toru; Yuri, Masaaki; Itoh, Kunio; Baba, T.; Harris, James S.

doi:10.1063/1.373783

Cited by 37 publications

(25 citation statements)

References 18 publications

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“…Calculation results showed that the strain energy distributes around O atoms and that the total strain energy is lower in ZnSO than in ZnSeO. The strain energy of the ternary alloy, U, can be expressed by the following equation [8]:…”

Section: Resultsmentioning

confidence: 99%

MBE growth of ZnSSeO alloy using ZnS as a sulfur source

Nabetani

Ito

Mukawa

et al. 2004

Physica Status Solidi (b)

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We have grown quaternary alloy semiconductor ZnSSeO by molecular beam epitaxy. Large band gap bowing due to large electronegativity of O is expected in this alloy. The growth of ZnSSeO was proceeded by supplying RF-excited oxygen during the growth of ZnSSe. The lattice constant of ZnSSeO decreased with increasing O 2 flow rate. X-ray diffraction peak was separated when O 2 flow rate was high. However, controllable range of lattice constant without phase separation was expanded compared with ZnSeO ternary alloy. It was shown that S composition parasitically increased with O composition. We have explained the enhancement of S incorporation in terms of reduction of strain energy. The band gap energy decreased with increasing O 2 flow rate regardless of phase separation. The amount of band gap bowing was slightly less than that found in ZnSeO. We have grown ZnSeO alloy by molecular beam epitaxy (MBE) and found large band gap bowing [4]. In ZnSeO ternary alloy, however, O composition influences both band gap energy and lattice constant. In order to control the band gap energy keeping the lattice constant fixed, a quaternary alloy is necessary. Moreover, phase separation was found in high O composition ZnSeO alloy due to a 19 % difference in bond length between ZnO and ZnSe [5]. In this work, we have grown ZnSSeO quaternary alloy. The smaller difference in bond length between ZnO and ZnS (15 %) than that between ZnO and ZnSe is advantageous in suppressing the internal lattice strain.

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Section: Resultsmentioning

confidence: 99%

MBE growth of ZnSSeO alloy using ZnS as a sulfur source

Nabetani

Ito

Mukawa

et al. 2004

Physica Status Solidi (b)

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“…The solid-solid miscibility characteristics of these semiconducting alloys have been studied, generally, assuming the regular solution model as the mixing model [1][2][3][4][5][6][7][8][9][10][11]. The interaction parameter (O) in the regular solution theory has been determined using various methods.…”

Section: Introductionmentioning

confidence: 99%

Molecular simulation predictions of miscibility characteristics and critical exponents in compound semiconductors

Sikder¹,

Rathi²,

Adhikari³

2011

Journal of Crystal Growth

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“…The parameters [6,7] used in this study are given in Table 1. Table 1 Parameters for the Valence Force Field model (Refs.…”

Section: Valence Force Field Modelmentioning

confidence: 99%

“…Takayama et al [6,7] have since refined the molecular model and have determined the miscibility characteristics and microstructure of other ternary and quaternary compound semiconductor alloys using the energy minimization approach of Ho and Stringfellow [3,4]. Adhikari and Kofke [8,9] used the molecular simulation approach to predict the miscibility diagram and local composition using the Valence Force Field (VFF) model for the InGaN, InAlN, GaAlN and InGaAlN alloys.…”

Section: Introductionmentioning

confidence: 99%

Molecular simulation study of the structural properties in InxGa1−xAs alloys: Comparison between Valence Force Field and Tersoff potential models

Adhikari

2008

Computational Materials Science

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Theoretical analysis of unstable two-phase region and microscopic structure in wurtzite and zinc-blende InGaN using modified valence force field model

Cited by 37 publications

References 18 publications

MBE growth of ZnSSeO alloy using ZnS as a sulfur source

MBE growth of ZnSSeO alloy using ZnS as a sulfur source

Molecular simulation predictions of miscibility characteristics and critical exponents in compound semiconductors

Molecular simulation study of the structural properties in InxGa1−xAs alloys: Comparison between Valence Force Field and Tersoff potential models

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