Abstract
Neutron grating interferometry (nGI) is a unique technique allowing to probe magnetic and nuclear properties of materials not accessible in standard neutron imaging. The signal-to-noise ratio of an nGI setup is strongly dependent on the achievable visibility. Hence, for analysis of weak signals or short measurement times a high visibility is desired. We developed a new Talbot-Lau interferometer using the third Talbot order with an unprecedented visibility (0.74) over a large field of view. Using the third Talbot order and the resulting decreased asymmetry allows to access a wide correlation length range. Moreover, we have used a novel technique for the production of the absorption gratings which provides nearly binary gratings even for thermal neutrons. The performance of the new interferometer is demonstrated by visualizing the local magnetic domain wall density in electrical steel sheets when influenced by residual stress induced by embossing. We demonstrate that it is possible to affect the density of the magnetic domain walls by embossing and therefore to engineer the guiding of magnetic fields in electrical steel sheets. The excellent performance of our new setup will also facilitate future studies of dynamic effects in electric steels and other systems.
Highlights
Neutron grating interferometry is a unique technique allowing to probe magnetic and nuclear properties of materials not accessible in standard neutron imaging
In this work we demonstrate the capabilities of our novel Neutron grating interferometry (nGI) setup to study the magnetic domain structure of non grain-oriented electrical steel sheets[33]
To develop and optimize the new design of the nGI setup we implemented a wave-optical simulation software based on a Fresnel-propagator[39] and numerical convolution calculations, which quantitatively describe the formation of the fringe contrast that is created by the three gratings G0, G1, and G225,40
Summary
Neutron grating interferometry (nGI) is a unique technique allowing to probe magnetic and nuclear properties of materials not accessible in standard neutron imaging. G2 allows for a wide quantitative analysis voafrtihaetimonicorfotshtreuccoturrreelawtiitohninletnhgethsaξm=pleλ20L,2sd2,/2p4.2 (see Sec. 4.2) of Firstly, changing the the setup, which enables a position of the sample allows operation of the nGI at the design wavelength with constantly high visibility and constantly good signal-to-noise ratio.
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