PFC emissions reduction and process improvements with remote plasma CVD chamber cleans

被引：0

作者：

Mendicino, L ^{[1
]}

Brown, PT ^{[1
]}

Filipiak, S ^{[1
]}

Nauert, C ^{[1
]}

Estep, H ^{[1
]}

Fletcher, M ^{[1
]}

机构：

[1] Motorola Inc, Digital DNA TM Labs, Austin, TX 78721 USA

来源：

ENVIRONMENTAL ISSUES WITH MATERIALS AND PROCESSES FOR THE ELECTRONICS AND SEMICONDUCTOR INDUSTRIES V | 2002年 / 2002卷 / 15期

关键词：

D O I：

暂无

中图分类号：

O646 [电化学、电解、磁化学];

学科分类号：

081704 ;

摘要：

For the past several years, the semiconductor industry has been striving to reduce emissions of perfluorocompounds (PFCs) as they are suspected global warming agents. Working with tool and chemical suppliers, semiconductor companies have been investigating technologies to reduce PFC emissions from CVD chamber cleaning and etch processes. Remote plasma chamber cleaning using NF3 has been demonstrated to reduce PFC emissions from chamber clean processes by 95% or greater. In addition to PFC emissions reduction, remote plasma cleans have provided process improvements, such as reduced clean time, improved film uniformity, and reduced particle generation. By implementing NF3-based chamber cleans, a modem 200 mm fab can likely achieve emissions reduction goals.

引用

页码：144 / 156

页数：13

共 28 条

[11] New alternative gas process feasibility study for PFC emission reduction from semiconductor CVD chamber cleaning
Beppu, T
Mitsui, Y
Sakai, K
Sekiya, A
GREENHOUSE GAS CONTROL TECHNOLOGIES, VOLS I AND II, PROCEEDINGS, 2003, : 1269 - 1274
[12] Further evaluation of two plasma technologies for PFC emissions reduction
Worth, Walter F.
SSA Journal: Journal of the Semiconductor Safety Association, 2000, 14 (04): : 11 - 19
[13] PFC emission reduction and atomic fluorine generation using C3F8 and remote CVD chamber clean technology
Zazzera, L
Kesari, S
Reagen, W
Tousignant, L
Holber, W
Chen, X
ENVIRONMENTAL ISSUES IN THE ELECTRONICS AND SEMICONDUCTOR INDUSTRIES, 1999, 99 (08): : 10 - +
[14] Charged particles in the reactor chamber of a remote plasma enhanced CVD system
Sirghi, L
Popa, G
Hatanaka, Y
PLASMA PHYSICS, 2003, 669 : 369 - 372
[15] Global energy & emissions reduction potential of chemical process improvements
Rightor, Edward G.
Tway, Cathy L.
CATALYSIS TODAY, 2015, 258 : 226 - 229
[16] Plasma damage reduction for high density plasma CVD phosphosilicate glass process
Chen, SW
Fu, CY
Jang, SM
Yu, CH
Liang, MS
2002 7TH INTERNATIONAL SYMPOSIUM ON PLASMA- AND PROCESS-INDUCED DAMAGE, 2002, : 76 - 79
[17] CO2 Emissions Reduction and Energy Efficiency Improvements in Paper Making Drying Process Control by Sensors
Miguel Calvo, Luis
Domingo, Rosario
SUSTAINABILITY, 2017, 9 (04):
[18] PFC emissions reduction using a one step clean optimization process on an applied materials P5000 TEOS system
Streif, T
DePinto, G
Dunnigan, S
Atherton, A
PROCEEDINGS OF THE SYMPOSIUM ON ENVIRONMENTAL ASPECTS OF ELECTROCHEMICAL TECHNOLOGY: APPLICATIONS IN ELECTRONICS, 1997, 96 (21): : 98 - 110
[19] Process optimization and PFC emission reduction using a c-C4F8 chamber cleaning process on a novellus concept 1 dielectric PECVD tool
Chan, EM
Loh, G
Allgood, CC
IEEE TRANSACTIONS ON SEMICONDUCTOR MANUFACTURING, 2004, 17 (04) : 497 - 503
[20] Ultrathin CVD Cu seed layer formation using copper oxynitride deposition and room temperature remote hydrogen plasma reduction
Kim, Hoon
Bhandari, Harish B.
Xu, Sheng
Gordon, Roy G.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 2008, 155 (07) : H496 - H503

← 1 2 3 →