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Silver Damascene Process with Cap Layer

Published online by Cambridge University Press:  01 February 2011

Masahiro Ota
Affiliation:
Department of mechanical engineering, graduate school of eng.Tokyo Metropolitan University 1-1, Minami-Oosawa, Hachi-oji, Tokyo, Japan
Manabu Tsujimura
Affiliation:
Precision Machinery Group, Ebara Corporation 5-37-1 Kamata Ohta-ku Tokyo Japan
Hiroaki Inoue
Affiliation:
Precision Machinery Group, Ebara Corporation 5-37-1 Kamata Ohta-ku Tokyo Japan
Hirokazu Ezawa
Affiliation:
Toshiba Corp. Semiconductor Company 8,Shinsugita-cho, Isogo-ku, Yokohama, Japan
Masahiro Miyata
Affiliation:
Toshiba Corp. Semiconductor Company 8,Shinsugita-cho, Isogo-ku, Yokohama, Japan
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Abstract

Development of semiconductors has proceeded according to broad frameworks such as the International Technology Roadmap for Semiconductors (ITRS). A key development in semiconductor technology involves the adoption of several new materials, such as Cu, low-k and high-k materials, and noble metals in capacitors, transistors, and/or interconnects. These developments will likely lead to wider application of the planarization process to new processes and new materials, and call for even stricter planarization performance requirements. One example involves planarizing Ag interconnects with an optimal cap layer configuration for reducing RC delays. The Cu interconnect process is currently used to reduce wire resistivity. One material that has been proposed as a successor to Cu is Ag. Many low-k materials have been developed with the goal of reducing dielectric constant (k). However, damascene design and matters such as cap layer configuration are also important considerations in reducing the effective dielectric constant (k eff). Our report herein begins by proposing Ni-B deposited by electroless plating as a candidate cap material, due to the following characteristics: (1) it offers good selectivity for Ag interconnects; (2) it provides good barrier effects through thermal processes; and (3) it provides good controllability of deposition rates. Next, we report that Ag damascene with Ni-B cap layer can be realized through electroplating and polishing of Ag interconnects. Although Ag polishing technologies are currently not fully developed, we suggest that they may nevertheless be successfully applied to polish Ag.

Type
Research Article
Copyright
Copyright © Materials Research Society 2002

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References

1) Tsujimura, M., Ni-B Electroless Plating as Cap Layer for Ag Multi-Level Metallization, Japan Institute of Electronics Packaging, 2002 Jan.Google Scholar
2) Ohno, Izimu, Electrical Chemical, vol 53. No.3, p. 196. 1985 Google Scholar
3) Hayashi, Tadao, Electroless plating, Nikkan Kogyo, p. 41, 1994 Google Scholar