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Fatigue Processes in Silicon MEMS Devices

Published online by Cambridge University Press:  21 March 2011

Emily D. Renuart
Affiliation:
Department of Materials Science and Engineering, Stanford University, CA 94305-2205
Alissa M. Fitzgerald
Affiliation:
Sensant Corporation, 650 Saratoga Ave., San Jose, CA 95129
Thomas W. Kenny
Affiliation:
Department of Mechanical Engineering, Stanford University, CA 94305
Reinhold H. Dauskardt
Affiliation:
Department of Materials Science and Engineering, Stanford University, CA 94305-2205
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Abstract

MEMS devices may experience significant alternating loads during service, associated with both applied and vibrational loading. Long-term reliability and lifetime predictions require understanding of possible fatigue mechanisms in these structures. Although silicon is not generally considered susceptible to fatigue crack growth, recent studies suggest that there may be fatigue processes in silicon MEMS structures. The phenomenon, however, has still not been extensively studied. In this work, we used a compressive double cantilever beam geometry to examine stable crack growth. Crack length and loads were carefully monitored throughout the test in order to distinguish between the apparent role of environmentally assisted crack growth (stress corrosion) and mechanically induced fatigue. Results revealed similar step-like crack extension versus time for the cyclic and monotonic tests. The fatigue crack-growth curve extracted from the crack extension data exhibited a nearly vertical slope with no evidence of fatigue crack-growth. Fracture surfaces for the monotonic and cyclic tests were similar, further suggesting that a true mechanical fatigue crack-growth mechanism did not occur.

Type
Research Article
Copyright
Copyright © Materials Research Society 2001

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References

REFERENCES

1. Yi, T. and Kim, C., Meas. Sci. Technol. 10, 706716 (1999).Google Scholar
2. Dauskardt, R. H., Marshal, D. B. and Ritchie, R. O., J. Am. Ceram. Soc. 73 (4), 893903 (1990).Google Scholar
3. Dauskardt, R. H., Acta Metall. Mater. 41 (9), 27652781 (1993).Google Scholar
4. Mutoh, M., Iyoda, M., and Fujita, K., Proc. of 1990 IEEE Workshop on Electronic Applications in Transportation. 1990, 3538.Google Scholar
5. Brown, S. B., Povirk, G., and Connally, J., IEEE Microelectromechanical Systems. 1993, 99104.Google Scholar
6. Ye, X.Y., Zhou, Z.Y., Yang, Y., Zhang, J.H., and Yao, J., Solid-State Sensors and Actuators, 1995 and Eurosensors IX, Transducers '95. 1995, 100103.Google Scholar
7. Tsuchiya, T., Inoue, A., Sakata, J., Hashimoto, M., Yokoyama, A., and Sugimoto, M., Technical Digest of the 16th Sensor Symposium. 1998, 277280.Google Scholar
8. Muhlstein, C., Brown, S., and Ritchie, R.O., J. MEMS. 2001 (in press).Google Scholar
9. Ritchie, R.O., International Journal of Fracture. 100, 5583 (1999).Google Scholar
10. Gonzalez, A.C. and Pantano, C.G., J. Am. Ceram. Soc. 73 (8), 25342535 (1990).Google Scholar
11. Liaw, P.K., Logsdon, W.A., Roth, L.D., and Hartmann, H.-R., ASTM Special Technical Publication, 1985, 177196.Google Scholar
12. Fitzgerald, A.M., Dauskardt, R.H., and Kenny, T.W., Sensors and Actuators A, 83, 194199 (2000).Google Scholar
13. Fitzgerald, A.M., Iyer, R.S., Dauskardt, R.H., and Kenny, T.W., J. Mat. Res. 2001 (in preparation).Google Scholar
14. Fitzgerald, A.M., PhD. Thesis, Stanford University, 2000.Google Scholar