| FUNDAMENTAL AREAS OF PHENOMENOLOGY(INCLUDING APPLICATIONS) |
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A Reflective Nonlinear Acoustic Microscope to Contour the Quantitative Adhesion at a Bonded Solid-Solid Interface |
| CHEN Jian-Jun**, ZHANG De, LIU Xiao-Zhou |
Key Laboratory of Modern Acoustics, and Institute of Acoustics, Nanjing University, Nanjing 210093
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| Cite this article: |
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CHEN Jian-Jun, ZHANG De, LIU Xiao-Zhou 2014 Chin. Phys. Lett. 31 094301 |
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Abstract We set up a reflective nonlinear acoustic microscope to contour the quantitative adhesion at a bonded solid-solid interface by a contact acoustic nonlinearity (CAN) method. The principle of the reflective nonlinear acoustic microscope is described. After the vibration amplitude of the incident, focusing wave at the bonded interface is calculated, the standard adhesion with a complete bonding state is established by the tension test, the reflective CAN parameter is calibrated, and the quantitative contour of the adhesion at the interface can be obtained. The experimental contours of two samples are also presented. Compared with the transmitted microscope, the reflective one is more convenient and more suitable for practical applications.
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Published: 22 August 2014
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| PACS: |
43.25.+y
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(Nonlinear acoustics)
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81.70.Cv
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(Nondestructive testing: ultrasonic testing, photoacoustic testing)
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43.58.+z
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(Acoustical measurements and instrumentation)
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