The optimization of the high-temperature heat source for a MOCVD vacuum reactor

Hsien Chih Chiu; Chih Kai Hu; Hung I. Chien; Tomi T. Li; Pi Chen Tung

doi:10.1109/CSTIC.2015.7153475

The optimization of the high-temperature heat source for a MOCVD vacuum reactor

Hsien Chih Chiu, Chih Kai Hu, Hung I. Chien, Tomi T. Li, Pi Chen Tung

Department of Mechanical Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Semiconductor equipment usually can be divided into five sub-system modules, (a) heating system, (b) exhausting system, (c) injecting system, (d) power control and (e) vacuum chamber. Metal organic chemical vapor deposition (MOCVD) process is the key process to deposit epitaxy thin film, and the uniformity is determined by the distribution of susceptor temperature. This research focuses on the development of high temperature heat source. The finite element software helps to develop the best results about the optimized geometry of the heater, the thickness of the susceptor, and the distance between the heater and susceptor. Furthermore, the optimum geometry of heater is received by numerical analysis combined with power controller. Compare with the experiment, the confidence level of software is 92%.

Original language	English
Title of host publication	China Semiconductor Technology International Conference 2015, CSTIC 2015
Editors	Cor Claeys, Qinghuang Lin, David Huang, Hanming Wu, Ru Huang, Kafei Lai, Ying Zhang, Beichao Zhang, Kuochun Wu, Larry Chen, Steve Liang, Peilin Song, Hsiang-Lan Lung, Dong Chen, Qi Wang
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781479972418
DOIs	https://doi.org/10.1109/CSTIC.2015.7153475
State	Published - 8 Jul 2015
Event	2015 China Semiconductor Technology International Conference, CSTIC 2015 - Shanghai, China Duration: 15 Mar 2015 → 16 Mar 2015

Publication series

Name	China Semiconductor Technology International Conference 2015, CSTIC 2015

Conference

Conference	2015 China Semiconductor Technology International Conference, CSTIC 2015
Country/Territory	China
City	Shanghai
Period	15/03/15 → 16/03/15

Access to Document

10.1109/CSTIC.2015.7153475

Cite this

Chiu, H. C., Hu, C. K., Chien, H. I., Li, T. T., & Tung, P. C. (2015). The optimization of the high-temperature heat source for a MOCVD vacuum reactor. In C. Claeys, Q. Lin, D. Huang, H. Wu, R. Huang, K. Lai, Y. Zhang, B. Zhang, K. Wu, L. Chen, S. Liang, P. Song, H.-L. Lung, D. Chen, & Q. Wang (Eds.), China Semiconductor Technology International Conference 2015, CSTIC 2015 Article 7153475 (China Semiconductor Technology International Conference 2015, CSTIC 2015). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/CSTIC.2015.7153475

Chiu, Hsien Chih ; Hu, Chih Kai ; Chien, Hung I. et al. / The optimization of the high-temperature heat source for a MOCVD vacuum reactor. China Semiconductor Technology International Conference 2015, CSTIC 2015. editor / Cor Claeys ; Qinghuang Lin ; David Huang ; Hanming Wu ; Ru Huang ; Kafei Lai ; Ying Zhang ; Beichao Zhang ; Kuochun Wu ; Larry Chen ; Steve Liang ; Peilin Song ; Hsiang-Lan Lung ; Dong Chen ; Qi Wang. Institute of Electrical and Electronics Engineers Inc., 2015. (China Semiconductor Technology International Conference 2015, CSTIC 2015).

@inproceedings{2b04e76b40ae40c4bfce394fca188576,

title = "The optimization of the high-temperature heat source for a MOCVD vacuum reactor",

abstract = "Semiconductor equipment usually can be divided into five sub-system modules, (a) heating system, (b) exhausting system, (c) injecting system, (d) power control and (e) vacuum chamber. Metal organic chemical vapor deposition (MOCVD) process is the key process to deposit epitaxy thin film, and the uniformity is determined by the distribution of susceptor temperature. This research focuses on the development of high temperature heat source. The finite element software helps to develop the best results about the optimized geometry of the heater, the thickness of the susceptor, and the distance between the heater and susceptor. Furthermore, the optimum geometry of heater is received by numerical analysis combined with power controller. Compare with the experiment, the confidence level of software is 92%.",

author = "Chiu, {Hsien Chih} and Hu, {Chih Kai} and Chien, {Hung I.} and Li, {Tomi T.} and Tung, {Pi Chen}",

note = "Publisher Copyright: {\textcopyright} 2015 IEEE.; 2015 China Semiconductor Technology International Conference, CSTIC 2015 ; Conference date: 15-03-2015 Through 16-03-2015",

year = "2015",

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doi = "10.1109/CSTIC.2015.7153475",

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series = "China Semiconductor Technology International Conference 2015, CSTIC 2015",

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editor = "Cor Claeys and Qinghuang Lin and David Huang and Hanming Wu and Ru Huang and Kafei Lai and Ying Zhang and Beichao Zhang and Kuochun Wu and Larry Chen and Steve Liang and Peilin Song and Hsiang-Lan Lung and Dong Chen and Qi Wang",

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Chiu, HC, Hu, CK, Chien, HI, Li, TT & Tung, PC 2015, The optimization of the high-temperature heat source for a MOCVD vacuum reactor. in C Claeys, Q Lin, D Huang, H Wu, R Huang, K Lai, Y Zhang, B Zhang, K Wu, L Chen, S Liang, P Song, H-L Lung, D Chen & Q Wang (eds), China Semiconductor Technology International Conference 2015, CSTIC 2015., 7153475, China Semiconductor Technology International Conference 2015, CSTIC 2015, Institute of Electrical and Electronics Engineers Inc., 2015 China Semiconductor Technology International Conference, CSTIC 2015, Shanghai, China, 15/03/15. https://doi.org/10.1109/CSTIC.2015.7153475

The optimization of the high-temperature heat source for a MOCVD vacuum reactor. / Chiu, Hsien Chih; Hu, Chih Kai; Chien, Hung I. et al.
China Semiconductor Technology International Conference 2015, CSTIC 2015. ed. / Cor Claeys; Qinghuang Lin; David Huang; Hanming Wu; Ru Huang; Kafei Lai; Ying Zhang; Beichao Zhang; Kuochun Wu; Larry Chen; Steve Liang; Peilin Song; Hsiang-Lan Lung; Dong Chen; Qi Wang. Institute of Electrical and Electronics Engineers Inc., 2015. 7153475 (China Semiconductor Technology International Conference 2015, CSTIC 2015).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - The optimization of the high-temperature heat source for a MOCVD vacuum reactor

AU - Chiu, Hsien Chih

AU - Hu, Chih Kai

AU - Chien, Hung I.

AU - Li, Tomi T.

AU - Tung, Pi Chen

PY - 2015/7/8

Y1 - 2015/7/8

N2 - Semiconductor equipment usually can be divided into five sub-system modules, (a) heating system, (b) exhausting system, (c) injecting system, (d) power control and (e) vacuum chamber. Metal organic chemical vapor deposition (MOCVD) process is the key process to deposit epitaxy thin film, and the uniformity is determined by the distribution of susceptor temperature. This research focuses on the development of high temperature heat source. The finite element software helps to develop the best results about the optimized geometry of the heater, the thickness of the susceptor, and the distance between the heater and susceptor. Furthermore, the optimum geometry of heater is received by numerical analysis combined with power controller. Compare with the experiment, the confidence level of software is 92%.

AB - Semiconductor equipment usually can be divided into five sub-system modules, (a) heating system, (b) exhausting system, (c) injecting system, (d) power control and (e) vacuum chamber. Metal organic chemical vapor deposition (MOCVD) process is the key process to deposit epitaxy thin film, and the uniformity is determined by the distribution of susceptor temperature. This research focuses on the development of high temperature heat source. The finite element software helps to develop the best results about the optimized geometry of the heater, the thickness of the susceptor, and the distance between the heater and susceptor. Furthermore, the optimum geometry of heater is received by numerical analysis combined with power controller. Compare with the experiment, the confidence level of software is 92%.

UR - http://www.scopus.com/inward/record.url?scp=84941243590&partnerID=8YFLogxK

U2 - 10.1109/CSTIC.2015.7153475

DO - 10.1109/CSTIC.2015.7153475

M3 - 會議論文篇章

AN - SCOPUS:84941243590

T3 - China Semiconductor Technology International Conference 2015, CSTIC 2015

BT - China Semiconductor Technology International Conference 2015, CSTIC 2015

A2 - Claeys, Cor

A2 - Lin, Qinghuang

A2 - Huang, David

A2 - Wu, Hanming

A2 - Huang, Ru

A2 - Lai, Kafei

A2 - Zhang, Ying

A2 - Zhang, Beichao

A2 - Wu, Kuochun

A2 - Chen, Larry

A2 - Liang, Steve

A2 - Song, Peilin

A2 - Lung, Hsiang-Lan

A2 - Chen, Dong

A2 - Wang, Qi

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 2015 China Semiconductor Technology International Conference, CSTIC 2015

Y2 - 15 March 2015 through 16 March 2015

ER -

Chiu HC, Hu CK, Chien HI, Li TT, Tung PC. The optimization of the high-temperature heat source for a MOCVD vacuum reactor. In Claeys C, Lin Q, Huang D, Wu H, Huang R, Lai K, Zhang Y, Zhang B, Wu K, Chen L, Liang S, Song P, Lung HL, Chen D, Wang Q, editors, China Semiconductor Technology International Conference 2015, CSTIC 2015. Institute of Electrical and Electronics Engineers Inc. 2015. 7153475. (China Semiconductor Technology International Conference 2015, CSTIC 2015). doi: 10.1109/CSTIC.2015.7153475

The optimization of the high-temperature heat source for a MOCVD vacuum reactor

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