TiN Hard Mask Cleans with SC1 Solutions, for 64nm Pitch BEOL Patterning-Reference-Cited by-同舟云学术

TiN Hard Mask Cleans with SC1 Solutions, for 64nm Pitch BEOL Patterning

Published:2014-09 Issue: Volume:219 Page:209-212
ISSN:1662-9779
Container-title:Solid State Phenomena
language:
Short-container-title:SSP

Author:

Broussous Lucile¹,Krejcirova D.¹,Courouble K.¹,Zoll S.¹,Iwasaki A.²,Ishikawa H.²,Buisine F.²,Lamaury A.²,Fuard D.³

Affiliation:

1. STMicroelectronics

2. Dainippon Screen Mtg. Co., Ltd.

3. Grenoble University

Abstract

Titanium Nitride metal hard mask was first introduced for BEOL patterning at 65 nm [1] and 45 nm nodes [2]. Indeed, in this “Trench First Hard Mask” (TFHM) backend architecture, the dual hard mask stack (SiO2 & TiN) allows a minimized exposure of ULK materials to damaging plasma chemistries, both for line/via etch sequence, and lithography reworks operations. This integration scheme was successfully used for a BEOL pitch down to 90 nm for the 28 nm node, however, for the 14 nm technology node, 64 nm BEOL minimum pitch is required for the first metal levels. Because it is unable to resolve features below 80 nm pitch in a single exposure, conventional 193 nm immersion lithography must be associated with dual patterning schemes, so called Lithography-Etch-Lithography-Etch (LELE) patterning [3] for line levels and self-aligned via (SAV) process [4] for via patterning. In both cases, 2 lithography/etch/clean sequences are necessary to obtain one desired pattern, and associated reworks also become more challenging since first pattern is exposed to resist removal processes (plasma + wet clean). The reference wet cleans that were developed for 65 to 28 nm TiN hardmask patterning, utilizes commonly used chemistry for BEOL post-etch cleans, i.e. diluted hydrofluoric acid (dHF) followed by deionized water Nanospray (DIWNS) on 300 mm single wafer tool.

Publisher

Trans Tech Publications, Ltd.

Subject

Condensed Matter Physics,General Materials Science,Atomic and Molecular Physics, and Optics

Link

https://www.scientific.net/SSP.219.209.pdf

Reference7 articles.

1. R. Fox et al., High Performance k=2. 5 ULK Backend Solution Using an Improved TFHM Architecture, Extendible to the 45nm Technology Node, IEDM 2005 Technical Digest, IEEE International, pp.81-84. DOI: 10. 1109/IEDM. 2005. 1609272.

2. E. Richard et al., Manufacturability and Speed Performance Demonstration of Porous ULK (k=2. 5) for a 45nm CMOS Platform, VLSI Technology, 2007 IEEE Symposium, p.178 – 179. DOI: 10. 1109/VLSIT. 2007. 4339683.

3. Yannick Loquet et al., 56nm pitch Cu dual-damascene interconnects with self-aligned via using negative-tone development Lithography-Etch-Lithography-Etch patterning scheme, Microelectronic Engineering 107 (2013), pp.138-144.

4. S. Goldberg et al., 64nm pitch interconnects: Optimized for designability, manufacturability and extendibility, Symposium on VLSI Technology (VLSIT), 2013 IEEE Conference Publications p. T202 - T203.

5. Handbook of Semiconductor Manufacturing Technology, Second Edition, Yoshio Nishi, Robert Doering (1990).

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