Andreas MANDELIS
Dynamic thermal-wave coherence tomographies for NDT and Biomedical Imaging By Andreas MANDELIS Center for Advanced Diffusion-Wave Technologies (CADIFT), Department of Mechanical and Industrial Engineering, University of Toronto, Toronto, Ontario, M5S 3G8, Canada.
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Abstract.Energy transport in diffusion-wave fields is gradient driven and therefore diffuse, yieldingdepth-integratedresponses with poor axial resolution. Traditional diffusion-wave techniques, limited by the physics of parabolic diffusion, can only produce depth-integrated planar images as they are unable to generate three-dimensional subsurface imaging. This talk will present two new imaging methods developed in the CADIFT for enabling parabolic thermal-wave fields to exhibit energy localization akin to propagating hyperbolic wave-fields. This approach when used with a mid-IR camera results indepth-selective(or depth-resolved) photothermal imaging which not only improves axial and depth resolution, but also allows for deconvolution of individual responses of superposed axially discrete sources, opening a new field of subsurface Photothermal Coherence Tomography (PCT) using thermal waves. In this talk I will present two novel thermal-wave imaging methodologies: Matched filter binary phase coded (BPC) PCT and truncated-correlation photothermal coherence tomography (TC-PCT). The physical principles of these methodologies and examples of imaging applications to engineering materials and biomaterials will be discussed.
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