Erik Thiel scite author profile

Erik Thiel

5Publications

37Citation Statements Received

56Citation Statements Given

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Affiliations

Federal Institute For Materials Research and Testing, World of Medicine (Germany), Staatliche Akademie der Bildenden Künste Stuttgart

Publications

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Laser-projected photothermal thermography using thermal wave field interference for subsurface defect characterization

Thiel

Kreutzbruck

Ziegler

2016

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The coherent superposition of two anti-phased thermal wave fields creates a zone of destructive interference which is extremely sensitive to the presence of defects without any reference measurements. Combining a high power laser with a spatial light modulator allows modulating phase and amplitude of an illuminated surface that induces spatially and temporally controlled thermal wave fields. The position and depth of defects are reconstructed from analysis of the amplitude and phase of the resulting photothermal signal. The proposed concept is experimentally validated and supported by numerical modeling.

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Blind structured illumination as excitation for super-resolution photothermal radiometry

Burgholzer

Berer

Ziegler

et al. 2019

Quantitative InfraRed Thermography Journal

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Blind structured illumination as excitation for super-resolution photothermal radiometry

Burgholzer

Berer

Ziegler

et al. 2018

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Using an infrared camera for radiometric imaging allows the contactless temperature measurement of multiple surface pixels simultaneously. From the measured surface data, a sub-surface structure, embedded inside a sample or tissue, can be reconstructed and imaged when heated by an excitation light pulse. The main drawback in radiometric imaging is the degradation of the spatial resolution with increasing depth, which results in blurred images for deeper lying structures. We circumvent this degradation with blind structured illumination, combined with a non-linear joint sparsity reconstruction algorithm. The groundbreaking concept of super-resolution can be transferred from optics to thermographic imaging.

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Wide-field, high-resolution two-photon tissue mapping of human skin ex vivo

Göppner

Mechow

Liebscher

et al. 2011

Medical Laser Application

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Thermography using a 1D laser array – From planar to structured heating

Ziegler¹,

Thiel²,

Studemund³

2018

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In the field of optically excited thermography, flash lamps (impulse-shaped planar heating) and halogen lamps (modulated planar heating) have become established for the specific regimes of impulse and lock-in thermography. Flying-spot laser thermography is implemented by means of a rasterized focused laser, e. g. for crack detection (continuous wave operation) and photothermal material characterization (high-frequency modulated). The availability of novel technologies, i. e. fast and high-resolution IR cameras, brilliant innovative light sources and high-performance data acquisition and processing technology will enable a paradigm shift from stand-alone photothermal and thermographic techniques to uniform quantitative measurement and testing technology that is faster and more precise. Similar to an LED array, but with irradiance two orders of magnitude higher, a new type of brilliant laser source, i. e. the VCSEL array (vertical-cavity surface-emitting laser), is now available. This novel optical energy source eliminates the strong limitation to the temporal dynamics of established light sources and at the same time is spectrally clearly separated from the detection wavelength. It combines the fast temporal behavior of a diode laser with the high optical irradiance and the wide illumination area of flash lamps. In addition, heating can also be carried out in a structured manner, because individual areas of the VCSEL array can be controlled independently of each other. This new degree of freedom enables the development of completely new thermographic NDT methods.

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Erik Thiel

Laser-projected photothermal thermography using thermal wave field interference for subsurface defect characterization

Blind structured illumination as excitation for super-resolution photothermal radiometry

Blind structured illumination as excitation for super-resolution photothermal radiometry

Wide-field, high-resolution two-photon tissue mapping of human skin ex vivo

Thermography using a 1D laser array – From planar to structured heating

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