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Mapping Residual-Stress Distributions in a Laser-Peened Vit-105 Bulk-Metallic Glass Using the Focused-Ion-Beam Micro-Slitting Method

Published online by Cambridge University Press:  11 March 2011

B. Winiarski
Affiliation:
School of Materials, The University of Manchester, Grosvenor St., Manchester, M1 7HS, UK
G. Wang
Affiliation:
Dept. of Materials Sci. & Eng., The University of Tennessee, Knoxville, TN 37996, USA
X. Xie
Affiliation:
Dept. of Materials Sci. & Eng., The University of Tennessee, Knoxville, TN 37996, USA
Y. Cao
Affiliation:
School of Mechanical Engineering, Purdue University, West Lafayette, IN 47907, USA
Y. Shin
Affiliation:
School of Mechanical Engineering, Purdue University, West Lafayette, IN 47907, USA
P. K. Liaw
Affiliation:
Dept. of Materials Sci. & Eng., The University of Tennessee, Knoxville, TN 37996, USA
P. J. Withers
Affiliation:
School of Materials, The University of Manchester, Grosvenor St., Manchester, M1 7HS, UK
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Abstract

Measuring residual-stresses at the micron scale in glassy materials imposes experimental challenges, particularly when using diffraction, or other conventional laboratory methods, e.g., optical non-contact methods, grid methods, etc. In this short paper, a technique for mapping residual-stress profiles in amorphous materials with high spatial definition is used to measure residual-stresses in a laser-peened and fatigued bulk-metallic glass - Vit-105. The method involves local deposition of nano Pt dots patterns on the mapped region of the specimen and milling of a series of micro-slots of size 15 × 2 × 0.4 μm3 using the focused ion beam of a dual beam Field Emission Gun Scanning Electron Microscope / Focused Ion Gun (FEGSEM/FIB) instrument. The deformation fields in the vicinity of slots are reconstructed by the digital image correlation analyses (DICA) of FEGSEM images recorded during milling. The residual-stresses are inferred by fitting a reference displacement field obtained from finite-element analyses (FEA) with the recorded displacement field. In this way, residual-stress distributions have been characterized as a function of the distance from the laser-peened surface to a depth of 1,200 microns with a spatial resolution of 30 μm. The influence of fatigue loading on the compressive residual-stresses spatial distribution is studied and discussed. It was found that the fatigue loading significantly changes the compressive residual-stress spatial distribution in the laser-peened layer.

Type
Research Article
Copyright
Copyright © Materials Research Society 2011

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References

REFERENCES

1. Johnson, W.L., Bulk glass-forming metallic alloys: Science and technology . MRS Bulletin, 1999. 24(10): p. 4256.Google Scholar
2. Inoue, A., Yoshii, I., Kimura, H., Okumura, K. and Kurosaki, J., Enhanced shot peening effect for steels by using Fe-based glassy alloy shots . Materials Transactions, 2003. 44(11): p. 23912395.Google Scholar
3. Fukushige, T., Hata, S., and Shimokohbe, A., A MEMS conical spring actuator array . Journal of Microelectromechanical Systems, 2005. 14(2): p. 243253.Google Scholar
4. Sun, D., Wang, S., Hata, S., Sakurai, J. and Shimokohbe, A., Cylindrical ultrasonic linear microactuator based on quasi-traveling wave propagation on a thin film metallic glass pipe supported by a piezoelectric ceramic tube . Sensors and Actuators A: Physical, 2009. 156(2): p. 359365.Google Scholar
5. Das, J., Tang, M.B., Kim, K.B., Theissmann, R., Baier, F., Wang, W.H. and Eckert, J., “Work-hardenable” ductile bulk metallic glass . Physical Review Letters, 2005. 94(20).Google Scholar
6. Loffler, J.F., Bulk metallic glasses . Intermetallics, 2003. 11(6): p. 529540.Google Scholar
7. Zhang, Y., Wang, W.H., and Greer, A.L., Making metallic glasses plastic by control of residual-stress . Nature Materials, 2006. 5(11): p. 857860.Google Scholar
8. Berthe, L., Fabbro, R., Peyre, P., Tollier, L. and Bartnicki, E., Shock Waves from A Water-confined Laser-generated Plasma . Journal of Applied Physics, 1997. 82(6): p. 28262832.Google Scholar
9. Montross, C.S., Tao, W., Ye, L., Clark, G. and Yiu-Wing, M., Laser shock processing and its effects on microstructure and properties of metal alloys: a review . International Journal of Fatigue, 2002. 24: p. 10211036.Google Scholar
10. Winiarski, B., Langford, R.M., Tian, J., Yokoyama, Y., Liaw, P.K. and Withers, P.J., Mapping residual-stress distributions at the micron scale in amorphous materials . Metallurgical and Materials Transactions A, 2009. 41(7): p. 17431751.Google Scholar
11. Poulsen, H.F., Wert, J.A., Neuefeind, J., Honkimaki, V. and Daymond, M., Measuring strain distributions in amorphous materials . Nature Materials, 2005. 4(1): p. 3336.Google Scholar
12. Das, J., Bostrom, M., Mattern, N., Kvick, A., Yavari, A.R., Greer, A.L. and Eckert, J., Plasticity in bulk metallic glasses investigated via the strain distribution . Physical Review B, 2007. 76(9).Google Scholar
13. Aydiner, C.C., Ustundag, E., Prime, M.B. and Peker, A., Modeling and measurement of residual-stresses in a bulk metallic glass plate . Journal Of Non-Crystalline Solids, 2003. 316(1): p. 8295.Google Scholar
14. Winiarski, B. and Withers, P.J., Mapping residual-stress profiles at the micron scale using FIB micro-hole drilling . Applied Mechanics and Materials, 2010. 24-25: p. 267272.Google Scholar