J. Schlichting scite author profile

We describe a novel experimental facility at the BESSY II synchrotron, aiming at probing element-specific magnetic properties at the nm-length scale. It consists of a novel photoemission electron microscope with photoelectron spin analysis combined with a microfocus beamline and full X-ray polarization control. The facility is capable of magnetic imaging in applied fields allowing the observation of magnetic switching phenomena on a 30-nm-length scale.

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Crack sizing by laser excited thermography

Schlichting

Maierhofer

Kreutzbruck

2012

NDT & E International

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Thermographic testing of spot welds

Schlichting

Brauser

Pepke

et al. 2012

NDT & E International

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Efficient data evaluation for thermographic crack detection

Schlichting

Ziegler

Dey

et al. 2011

Quantitative InfraRed Thermography Journal

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We present an all-purpose crack detection algorithm for flying spot thermography which is directly applicable to a thermogram sequence without the need of any additional information about the experimental setup. A single image containing distinct crack signatures is derived in two steps. Firstly, the spatial derivative is calculated for each frame of the sequence and, secondly, the resulting data set is sorted pixel wise along the time axis. The feasibility of the proposed procedure is proven by testing a piece of rail that comprises roll contact fatigue cracks and by comparing the results with magnetic particle testing.

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Defect sizing by local excitation thermography

Schlichting¹,

Maierhoher²,

Kreutzbruck³

2011

QIRTJ

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In this article, we present a measurement procedure to gain information about depth and angle of open surface cracks. The method is based on a local excitation with, e.g., a laser. The resulting surface temperature is recorded with an infrared camera. Based on this data, crack-caused anisotropies in the lateral heat flow can be detected and exploited to characterise the cracks.The experimental set-up is based on a Nd:YAG laser. The beam is focused on the test sample by using an optical scanner to generate the required lateral heat flow. The time resolved temperature distribution is recorded with a high-speed infrared camera (InSb FPA, 3 to 5 µm) providing a frame rate of up to 500 Hz.Up to now, only qualitative information was gained from measurements of this type. Whereas the local transient behaviour of temperature distribution provides also quantitative information of the crack parameters. The general concept of the method presented herein has already been published [1], but the mentioned publication is focused on the crack depth only.In this paper, we can show that it is possible to simultaneously resolve the angle and depth and, in particular, the depth of non-perpendicular cracks.

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J. Schlichting

Spin‐resolved photoemission microscopy and magnetic imaging in applied magnetic fields

Crack sizing by laser excited thermography

Thermographic testing of spot welds

Efficient data evaluation for thermographic crack detection

Defect sizing by local excitation thermography

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