Impulse excitation scanning acoustic microscopy for local quantification of Rayleigh surface wave velocity using B-scan analysis

A new technique for performing quantitative scanning acoustic microscopy imaging of Rayleigh surface wave (RSW) velocity was developed based on b-scan processing. In this technique, the focused acoustic beam is moved through many defocus distances over the sample and excited with an impulse excitati...

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Bibliographic Details
Published in:Review of scientific instruments 2018-01, Vol.89 (1), p.013706-013706
Main Authors: Cherry, M., Dierken, J., Boehnlein, T., Pilchak, A., Sathish, S., Grandhi, R.
Format: Article
Language:English
Subjects:
Acoustics
Crystallography
Excitation
Filtration
Hilbert transformation
Microscopy
Scanning acoustic microscopy
Scientific apparatus & instruments
Surface waves
Velocity
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Summary:A new technique for performing quantitative scanning acoustic microscopy imaging of Rayleigh surface wave (RSW) velocity was developed based on b-scan processing. In this technique, the focused acoustic beam is moved through many defocus distances over the sample and excited with an impulse excitation, and advanced algorithms based on frequency filtering and the Hilbert transform are used to post-process the b-scans to estimate the Rayleigh surface wave velocity. The new method was used to estimate the RSW velocity on an optically flat E6 glass sample, and the velocity was measured at ±2 m/s and the scanning time per point was on the order of 1.0 s, which are both improvement from the previous two-point defocus method. The new method was also applied to the analysis of two titanium samples, and the velocity was estimated with very low standard deviation in certain large grains on the sample. A new behavior was observed with the b-scan analysis technique where the amplitude of the surface wave decayed dramatically on certain crystallographic orientations. The new technique was also compared with previous results, and the new technique has been found to be much more reliable and to have higher contrast than previously possible with impulse excitation.
ISSN:0034-6748
1089-7623
DOI:10.1063/1.4998936