For non-contact non-destructive evaluation (NDE), a laser/EMAT system is an alternative to a more expensive all optical laser-ultrasound system. Several design options of the electromagnetic acoustic transducer (EMAT) are available, permitting inspection of electrically conducting materials. In this paper, we describe a system capable of monitoring variation in either sample thickness or defects, with time-of-flight diffraction arising from mode-converted ultrasonic waves. In a B-scan imaging configuration, quantitative time-of-flight analysis of laser-generated acoustic waves is shown to be an effective method for measurement. Various images will be presented together with an interpretation of their features. For these images, transient laser pulses with typical energies of ~18mJ have been delivered to the material surface via an optical fiber and focused to a line source by a cylindrical lens. Acoustic waves arising from this excitation propagated through the sample to be reflected from the far surface. Waves returning to the surface, including L-S and S-L mode-converted waves, were detected using an EMAT sensitive to in-plane motion. B-scans have been generated as the sensor head moved along the material's surface, forming a 2-D intensity profile that made changes in plate thickness easy to visualize. Both L-S and S-L mode-converted waves provided a method of simultaneously monitoring two different points on the far surface enabling any changes in the material thickness to be clearly identified.
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