Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-29T07:09:44.216Z Has data issue: false hasContentIssue false

Performance Comparisons of Abrasive Containing and Abrasive Free Slurries for Copper Low-k CMP

Published online by Cambridge University Press:  01 February 2011

Get access

Abstract

The commercially available abrasive containing slurries for copper CMP have shown some advantages in high removal rates, low friction at low down force, and minimal to no copper residues, regardless of the polisher architecture, either rotary, orbital, or linear polishing. However, the abrasive containing slurries have some disadvantages such as high dishing and erosion with more micro-scratches due to the presence of abrasives. In contrast, the abrasive free polishing slurry has lower removal rate, and seems to be sensitive to polishing architecture, but it has good planarization, low topography, less micro-scratches, and most importantly is insensitive to over-polish.

At this stage, the best results for copper CMP are being achieved by the use of the multi-step and multi-slurry process in which copper is polished first, and barrier layers are polished with a different set of consumables. The intent of this paper is to focus on the first step, the copper removal step, and to compare different approaches for this first step; namely, the use of slurries containing abrasives with slurries that are free of abrasives on the orbital polisher. The combined process with low percent solid and small-sized abrasives for the bulk copper removal step and abrasive free polishing (AFP) slurry for the residual copper removal step on an orbital polisher has produced a very robust process window with excellent results including low topography, low erosion, insensitivity to over-polish and low cost of ownership.

Type
Research Article
Copyright
Copyright © Materials Research Society 2002

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Gotkis, Y., Dai Jnguyen, F., Mitchell, F., Shumway, L., Yang Pnunan, J., and Holland, K., Selectivity Switch Concept in Cu CMP and Its Implementation on Orbital Tools. JVST. September 1999.Google Scholar
2. Hymes, S., Smekalin, K., Brown, T., Yeung, H., Joffe, M., Banet, M., Park, T., Tugbawa, T., Boning, D., Nguyen, J., West, T., Sands, W.. Evolution of Topography during 1st step CMP of Cu-plated Damascene Strutures., MRS, April, 1999 Google Scholar
3. Steigerwald, J. M., Murarka, S.P., and Gutmann, R., Chemical Mechanical Planarization of Microelectronic Matreials page 210-212, 239240.Google Scholar
4. Hymes, S., Smekalin, K., Brown, T., Yeung, H., Joffe, M., Banet, M., Park, T., Tugbawa, T., Boning, D., Nguyen, J., West, T., Sands, W.. Determination of the Planarization Distance for Copper CMP Process, MRS, Vol. 566 Google Scholar
5. Tugbawa, T., Boning, D., Lefevre, P., Nguyen, J., Modeling of Pattern Dependencies in Abrasive Free CMP Polishing Process, VMIC September 2001.Google Scholar