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Lift-off Methods for MEMS Devices

Published online by Cambridge University Press:  01 February 2011

Shih-Chia Chang  and
Jeffrey M. Kempisty
Shih-Chia Chang
Affiliation:
Delphi Research Laboratories51786 Shelby PKWY Shelby Twp, MI 48315-1786
Jeffrey M. Kempisty
Affiliation:
Delphi Research Laboratories51786 Shelby PKWY Shelby Twp, MI 48315-1786
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Abstract

Five different methods were explored for the formation of the lift-off mold. In the first method, a tri-level resist scheme was used to generate a lift-off mold. The lift-off mold has a vertical wall slope. In the second method, an aluminum/photoresist double layer was used as the mold material. An overhang structure is obtained by undercutting the underlying aluminum layer. In the third method, a composite layer of two different photoresists (AZ 1811 and LOR 10A) was used to form the lift-off mold. With the fast dissolution rate of the underlying LOR 10A photoresist an overhanging mask structure was obtained. Since regular photoresists were used as part of the mold material in these three lift-off methods, they are suitable for thin film materials with thickness of ≤2 μm and processing temperatures ≤100°C. For thicker device film materials and higher processing temperature (∼200°C), methods 4 and 5 using negative resists, Futurrex NR7-3000PY (∼3 μm) and SU-8 (∼50 μm), respectively, were experimented with to form the lift-off mask. The fabrication processes used in these two methods were relatively simple and a negative wall slope was readily obtained. While Futurrex photoresist is easily stripped by the resist remover provided by the manufacturer, there is no effective chemical solution available for the removal of SU-8. We found that plasma etching with a mixture of O2 and C2F6 can be used for the removal of SU-8.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 729: Symposium U – MEMS and BioMEMS , 2002 , U2.3
Copyright
Copyright © Materials Research Society 2002

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References

1.VLSI Technology,” Ed. Sze, S. M., Chapter 9, McGraw-Hill, (1983).Google Scholar
2. Sakurai, T. and Serikawa, T., ”Lift-Off Metallization of Sputtered Al Alloy Films,J. Electrochem. Soc., 126, 1257, (1979).Google Scholar
3. Batchelder, T., ”A Simple Metal Lift-Off Process,” Solid State TechNet., 25, 11 (1982).Google Scholar
4. Hatzakis, M., Canavello, B. J., Shaw, J. M., J., ”Single-Step Optical Lift-Off Process,” IBM Res. & Dev., Vol. 24, no. 4, p. 452, July (1980).Google Scholar
5. Moran, J. M. and Maydan, D., “High Resolution, Steep Profile Resist Patterns,” J. Vac. Sci. Technol., 16(60) p.1620 (1979).Google Scholar
6. Bruning, J. H., “Optical Imaging for Microfabrication,” J. Vac. Sci. Technol. 23(2), p.1147, (1980).Google Scholar
7. Chang, S.C., Putty, M. W. and Hicks, D. B., “The formation of Electroplating mold by Reactive Ion Etching”, Digest of Technical Papers, the 8th International Conference on Solid-State Sensors and Actuators, 577, (1995).Google Scholar
8. Loechel, B. and Maciossek, A., ”Surface Micro Components Fabricated by UV Depth Lithography and Electroplating”, Proceedings, SPIE Conference on Micromachining and Microfabrication Process Technology, p. 174, (1995).Google Scholar
9. Lee, K. Y., et al., “Micromachining Application of High Resolution Ultrathick Photoresist,” J. Vac. Technol., B 13(6) p. 3012 (1995)Google Scholar