论文信息 - Measurement of interface strength by the modified laser spallation technique. III. Experimental optimization of the stress pulse

Measurement of interface strength by the modified laser spallation technique. III. Experimental optimization of the stress pulse

In Part III of this series, experimental optimization of the laser spallation technique is achieved by investigating the effect of the kind and thickness of the constraining materials and the energy‐absorbing film on the amplitude and profile of the generated stress pulse. An experimental setup consisting of a 0.5‐μm‐thick Al film as the energy absorbing film and a 5 μm layer of solid water glass as the constraining material is found to maximize the stress pulse amplitude. In addition, the effect of the substrate material on the shape of the stress pulse is also determined. Finally, it was found that for a given substrate, the pulse profile is independent of the laser fluence, indicating similar laser‐material interaction phenomena over the range of fluence levels considered here.

[1] Robert Lee Melcher,et al. 20‐MHz acoustic waves from pulsed thermoelastic expansions of constrained surfaces , 1977 .

[2] V. Gupta,et al. Measurement of interface strength by laser-pulse-induced spallation , 1990 .

[3] C. H. Skeen,et al. Laser‐induced stress‐wave and impulse augmentation , 1972 .

[4] Richard M. White,et al. Generation of Elastic Waves by Transient Surface Heating , 1963 .

[5] V. Gupta,et al. Measurement of interface strength by a laser spallation technique , 1992 .

[6] David A. Hutchins,et al. Ultrasonic Generation by Pulsed Lasers , 1988 .

[7] J. Yuan,et al. Measurement of interface strength by the modified laser spallation technique. I - Experiment and simulation of the spallation process. II - Applications to metal/ceramic interfaces , 1993 .

[8] J. Fox. Effect of water and paint coatings on laser‐irradiated targets , 1974 .

[9] V. Gupta,et al. Measurement of interface strength by the modified laser spallation technique. II. Applications to metal/ceramic interfaces , 1993 .

[10] L. C. Yang. Stress waves generated in thin metallic films by a Q-switched ruby laser , 1974 .

[11] R. G. Jung,et al. Quantitative assessment of laser‐induced stress waves generated at confined surfaces , 1974 .

[12] R. S. Sharpe,et al. Research techniques in nondestructive testing , 1970 .