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Process Integration Of Low-Dielectric-Constant Materials

Published online by Cambridge University Press:  15 February 2011

Shin-Puu Jeng
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Kelly Taylor
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Mi-Chang Chang
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Larry Ting
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Charles Lee
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Peter Mcanally
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Tom Seha
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Ken Numata
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Tsuyoshi Tanaka
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
Robert H. Havemann
Affiliation:
Semiconductor Process And Device Center, Texas Instruments, Dallas, TX 75265
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Abstract

As device geometries and operating voltage continue to scale while functional density increases, it is imperative to reduce the RC time delay. The replacement of Si0 2 as an intermetal dielectric with an insulator of lower dielectric constant is a particularly attractive solution since it provides immediate performance improvement through reduction in capacitance. An embedded polymer integration scheme improves the interconnect performance through line-to-line capacitance reduction by using polymer only between tightly spaced lines. The gapfill polymeric materials do not degrade the electromigration performance of standard multilayered TiN/Al/TiN interconnects. Embedded polymers alleviate many of the integration and reliability problems associated with polymer integration, and can be easily adopted into a standard production process.

Type
Research Article
Copyright
Copyright © Materials Research Society 1995

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References

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