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Composition of III-V ternary materials under arbitrary material fluxes: the general approach unifying kinetics and thermodynamics. / Дубровский, Владимир Германович; Лещенко, Егор Дмитриевич.

в: Physical Review Materials, Том 7, № 7, 074603 , 14.07.2023.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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@article{751cb91575a6490f8184cb18eca5bab7,
title = "Composition of III-V ternary materials under arbitrary material fluxes: the general approach unifying kinetics and thermodynamics",
abstract = "Understanding and controlling the composition of III-V ternary nanomaterials is essential for band-gap tunability and fabrication of functional nanoheterostructures. The kinetic approach developed so far is based on the assumption of C-rich growth of a ternary AxB1-xC material based on intermix of A and B atoms. This holds for epilayers based on group III intermix, but is not true for epilayers based on group V intermix or vapor-liquid-solid nanowires based on group III intermix. Herein, we develop a general growth theory and obtain a vapor-solid distribution which described the ternary composition under arbitrary material fluxes and for any III-V material. This vapor-solid distribution is a combination of the kinetic and equilibrium distributions, whose weights depend on the ratio ϵ of the total flux of A and B atoms over the flux of C atoms. At ϵ≪1, the composition is kinetically controlled, while at ϵ≫1 it becomes thermodynamically limited even at infinitely high binary supersaturations for AC and BC pairs. The model fits very well the compositional data on the InSbxAs1-x epilayers, AlSbxAs1-x epilayers, and InSbxAs1-x nanowires under different total V/III flux ratios. It reveals some fundamental properties of the vapor-solid distribution beyond the assumption of decoupled binary fluxes. In particular, the vapor-solid distribution becomes purely thermodynamic and presents the miscibility gap below the critical temperature under AB-rich conditions for an AxB1-xC ternary regardless of the vapor supersaturation. The miscibility gap can be fully circumvented in the C-rich regime, where the solid composition is driven by the kinetic factors.",
author = "Дубровский, {Владимир Германович} and Лещенко, {Егор Дмитриевич}",
year = "2023",
month = jul,
day = "14",
doi = "10.1103/physrevmaterials.7.074603",
language = "English",
volume = "7",
journal = "Physical Review Materials",
issn = "2475-9953",
publisher = "American Physical Society",
number = "7",

}

RIS

TY - JOUR

T1 - Composition of III-V ternary materials under arbitrary material fluxes: the general approach unifying kinetics and thermodynamics

AU - Дубровский, Владимир Германович

AU - Лещенко, Егор Дмитриевич

PY - 2023/7/14

Y1 - 2023/7/14

N2 - Understanding and controlling the composition of III-V ternary nanomaterials is essential for band-gap tunability and fabrication of functional nanoheterostructures. The kinetic approach developed so far is based on the assumption of C-rich growth of a ternary AxB1-xC material based on intermix of A and B atoms. This holds for epilayers based on group III intermix, but is not true for epilayers based on group V intermix or vapor-liquid-solid nanowires based on group III intermix. Herein, we develop a general growth theory and obtain a vapor-solid distribution which described the ternary composition under arbitrary material fluxes and for any III-V material. This vapor-solid distribution is a combination of the kinetic and equilibrium distributions, whose weights depend on the ratio ϵ of the total flux of A and B atoms over the flux of C atoms. At ϵ≪1, the composition is kinetically controlled, while at ϵ≫1 it becomes thermodynamically limited even at infinitely high binary supersaturations for AC and BC pairs. The model fits very well the compositional data on the InSbxAs1-x epilayers, AlSbxAs1-x epilayers, and InSbxAs1-x nanowires under different total V/III flux ratios. It reveals some fundamental properties of the vapor-solid distribution beyond the assumption of decoupled binary fluxes. In particular, the vapor-solid distribution becomes purely thermodynamic and presents the miscibility gap below the critical temperature under AB-rich conditions for an AxB1-xC ternary regardless of the vapor supersaturation. The miscibility gap can be fully circumvented in the C-rich regime, where the solid composition is driven by the kinetic factors.

AB - Understanding and controlling the composition of III-V ternary nanomaterials is essential for band-gap tunability and fabrication of functional nanoheterostructures. The kinetic approach developed so far is based on the assumption of C-rich growth of a ternary AxB1-xC material based on intermix of A and B atoms. This holds for epilayers based on group III intermix, but is not true for epilayers based on group V intermix or vapor-liquid-solid nanowires based on group III intermix. Herein, we develop a general growth theory and obtain a vapor-solid distribution which described the ternary composition under arbitrary material fluxes and for any III-V material. This vapor-solid distribution is a combination of the kinetic and equilibrium distributions, whose weights depend on the ratio ϵ of the total flux of A and B atoms over the flux of C atoms. At ϵ≪1, the composition is kinetically controlled, while at ϵ≫1 it becomes thermodynamically limited even at infinitely high binary supersaturations for AC and BC pairs. The model fits very well the compositional data on the InSbxAs1-x epilayers, AlSbxAs1-x epilayers, and InSbxAs1-x nanowires under different total V/III flux ratios. It reveals some fundamental properties of the vapor-solid distribution beyond the assumption of decoupled binary fluxes. In particular, the vapor-solid distribution becomes purely thermodynamic and presents the miscibility gap below the critical temperature under AB-rich conditions for an AxB1-xC ternary regardless of the vapor supersaturation. The miscibility gap can be fully circumvented in the C-rich regime, where the solid composition is driven by the kinetic factors.

UR - https://www.mendeley.com/catalogue/840dbf25-1d85-3a09-ae40-0cfb1da2da91/

U2 - 10.1103/physrevmaterials.7.074603

DO - 10.1103/physrevmaterials.7.074603

M3 - Article

VL - 7

JO - Physical Review Materials

JF - Physical Review Materials

SN - 2475-9953

IS - 7

M1 - 074603

ER -

ID: 107099554