Thermodynamic modeling and phase diagrams of hexagonal and cubic GaN single-crystal film growth by ECR-PEMOCVD method

Sansheng Wang; Biao Gu

Thermodynamic modeling and phase diagrams of hexagonal and cubic GaN single-crystal film growth by ECR-PEMOCVD method

Sansheng Wang^*
, Biao Gu

^*Corresponding author for this work

Tsinghua University
Dalian University of Technology

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

Abstract

Based on thermodynamic equilibrium theory, a chemical equilibrium model for GaN growth is given in electron cyclotron resonance plasma enhanced metallorganic chemical vapor deposition (ECR-PEMOCVD) system. Calculation indicates that the growth driving force are functions of growth conditions: group III input partial pressure, input V/III ratio, and growth temperature. Furthermore, the growth phase diagrams of hexagonal and cubic GaN film growth are obtained, which are consistent with the experimental conditions to some extent. Through analysis, it is explained the reason that high temperature and high input V/III ratio are favorable for hexagonal GaN film growth. This model can be extended to the similar systems used for GaN single-crystal film growth.

Original language	English
Pages (from-to)	1041-1047
Number of pages	7
Journal	Pan Tao Ti Hsueh Pao/Chinese Journal of Semiconductors
Volume	25
Issue number	9
State	Published - Sep 2004
Externally published	Yes

Keywords

ECR-PEMOCVD
GaN
Growth phase diagram
Thermodynamic analysis

Cite this

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title = "Thermodynamic modeling and phase diagrams of hexagonal and cubic GaN single-crystal film growth by ECR-PEMOCVD method",

abstract = "Based on thermodynamic equilibrium theory, a chemical equilibrium model for GaN growth is given in electron cyclotron resonance plasma enhanced metallorganic chemical vapor deposition (ECR-PEMOCVD) system. Calculation indicates that the growth driving force are functions of growth conditions: group III input partial pressure, input V/III ratio, and growth temperature. Furthermore, the growth phase diagrams of hexagonal and cubic GaN film growth are obtained, which are consistent with the experimental conditions to some extent. Through analysis, it is explained the reason that high temperature and high input V/III ratio are favorable for hexagonal GaN film growth. This model can be extended to the similar systems used for GaN single-crystal film growth.",

keywords = "ECR-PEMOCVD, GaN, Growth phase diagram, Thermodynamic analysis",

author = "Sansheng Wang and Biao Gu",

year = "2004",

month = sep,

language = "英语",

volume = "25",

pages = "1041--1047",

journal = "Pan Tao Ti Hsueh Pao/Chinese Journal of Semiconductors",

issn = "0253-4177",

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TY - JOUR

T1 - Thermodynamic modeling and phase diagrams of hexagonal and cubic GaN single-crystal film growth by ECR-PEMOCVD method

AU - Wang, Sansheng

AU - Gu, Biao

PY - 2004/9

Y1 - 2004/9

N2 - Based on thermodynamic equilibrium theory, a chemical equilibrium model for GaN growth is given in electron cyclotron resonance plasma enhanced metallorganic chemical vapor deposition (ECR-PEMOCVD) system. Calculation indicates that the growth driving force are functions of growth conditions: group III input partial pressure, input V/III ratio, and growth temperature. Furthermore, the growth phase diagrams of hexagonal and cubic GaN film growth are obtained, which are consistent with the experimental conditions to some extent. Through analysis, it is explained the reason that high temperature and high input V/III ratio are favorable for hexagonal GaN film growth. This model can be extended to the similar systems used for GaN single-crystal film growth.

AB - Based on thermodynamic equilibrium theory, a chemical equilibrium model for GaN growth is given in electron cyclotron resonance plasma enhanced metallorganic chemical vapor deposition (ECR-PEMOCVD) system. Calculation indicates that the growth driving force are functions of growth conditions: group III input partial pressure, input V/III ratio, and growth temperature. Furthermore, the growth phase diagrams of hexagonal and cubic GaN film growth are obtained, which are consistent with the experimental conditions to some extent. Through analysis, it is explained the reason that high temperature and high input V/III ratio are favorable for hexagonal GaN film growth. This model can be extended to the similar systems used for GaN single-crystal film growth.

KW - ECR-PEMOCVD

KW - GaN

KW - Growth phase diagram

KW - Thermodynamic analysis

UR - https://www.scopus.com/pages/publications/11844265946

M3 - 文章

AN - SCOPUS:11844265946

SN - 0253-4177

VL - 25

SP - 1041

EP - 1047

JO - Pan Tao Ti Hsueh Pao/Chinese Journal of Semiconductors

JF - Pan Tao Ti Hsueh Pao/Chinese Journal of Semiconductors

IS - 9

ER -

Thermodynamic modeling and phase diagrams of hexagonal and cubic GaN single-crystal film growth by ECR-PEMOCVD method

Abstract

Keywords

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