Recent Progress in X-ray and Neutron Phase Imaging with Gratings

Momose, Atsushi; Takano, Hidekazu; Wu, Yanlin; Hashimoto, Kunihisa; Samoto, Tetsuo; Hoshino, Masato; Seki, Yoshichika; Shinohara, T.

doi:10.3390/qubs4010009

Cited by 22 publications

(15 citation statements)

References 102 publications

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“…Many of these experiments require an optimum or at least a properly defined beam wavefront (WF). Several X-rays WF sensing techniques have been proposed in the past: grating-based interferometry [ 1 ], speckle tracking [ 2 , 3 ], ptychography [ 4 , 5 , 6 ] and imaged-based wavefront sensing combined with machine learning [ 7 ]. Among these techniques, Hartmann WF sensing provides several advantages, such as achromaticity, very large dynamic range, real-time wavefront display and ease of use [ 8 , 9 , 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

EUV and Hard X-ray Hartmann Wavefront Sensing for Optical Metrology, Alignment and Phase Imaging

Rochefoucauld

Dovillaire

Harms

et al. 2021

Sensors

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For more than 15 years, Imagine Optic have developed Extreme Ultra Violet (EUV) and X-ray Hartmann wavefront sensors for metrology and imaging applications. These sensors are compatible with a wide range of X-ray sources: from synchrotrons, Free Electron Lasers, laser-driven betatron and plasma-based EUV lasers to High Harmonic Generation. In this paper, we first describe the principle of a Hartmann sensor and give some key parameters to design a high-performance sensor. We also present different applications from metrology (for manual or automatic alignment of optics), to soft X-ray source optimization and X-ray imaging.

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Section: Introductionmentioning

confidence: 99%

EUV and Hard X-ray Hartmann Wavefront Sensing for Optical Metrology, Alignment and Phase Imaging

Rochefoucauld

Dovillaire

Harms

et al. 2021

Sensors

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“…The technique of grating interferometry has been introduced to neutron imaging in 2006 as a tool for phase contrast imaging and it has gained substantial impact with the establishment of the neutron dark-field contrast modality, enabling structural studies beyond direct spatial image resolution 1 – 5 . Dark-field contrast imaging (DFI) provides contrast based on local small-angle scattering (SAS) in bulk samples and thus enabled the visualization of local microstructural inhomogeneities 6 – 8 .…”

Section: Introductionmentioning

confidence: 99%

Towards spatially resolved magnetic small-angle scattering studies by polarized and polarization-analyzed neutron dark-field contrast imaging

Valsecchi

Kim

Lee

et al. 2021

Sci Rep

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In the past decade neutron dark-field contrast imaging has developed from a qualitative tool depicting microstructural inhomogeneities in bulk samples on a macroscopic scale of tens to hundreds of micrometers to a quantitative spatial resolved small-angle scattering instrument. While the direct macroscopic image resolution around tens of micrometers remains untouched microscopic structures have become assessable quantitatively from the nanometer to the micrometer range. Although it was found that magnetic structures provide remarkable contrast we could only recently introduce polarized neutron grating interferometric imaging. Here we present a polarized and polarization analyzed dark-field contrast method for spatially resolved small-angle scattering studies of magnetic microstructures. It is demonstrated how a polarization analyzer added to a polarized neutron grating interferometer does not disturb the interferometric measurements but allows to separate and measure spin-flip and non-spin-flip small-angle scattering and thus also the potential for a distinction of nuclear and different magnetic contributions in the analyzed small-angle scattering.

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“…Many techniques have been implemented to perform X-ray Phase Contrast Tomography (XPCT) like Free-Space Propagation set-ups, 6,7 Talbot, 8 coded aperture 2 and interferometry. 9 For biological application measuring the density variations inside the tissues is an important parameter to differentiate morphological structures and their changes. Object densities are described by their index of refraction n(ω) = 1 − δ(ω) − iβ(ω), where ω is the wave pulsation , δ(ω) is proportional to the phase and β(ω) to the absorption.…”

Section: Introductionmentioning

confidence: 99%

Phase-Contrast Tomography with X-ray Hartmann wavefront sensor

Provinciali

Cedola

Rochefoucauld

et al. 2021

International Conference on X-Ray Lasers 2020

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The Hartmann wavefront sensor is able to measure, separately and in absolute, the real δ and imaginary parts β of the X-ray refractive index. While combined with tomographic setup, Hartmann sensor opens many interesting opportunities behind the direct measurement of the material density. In order to handle the different ways of using an X-ray wavefront sensor in imaging, we developed 3D wave propagation model based on Fresnel propagator. The model is made in a way to manage any degree of spatial coherence of the source, thus enabling to model accurately experiments using tabletop source, high harmonic generation, plasma-based soft X-ray laser, synchrotron or X-ray free-electron laser. Beam divergence is described in a physical manner consistent with the spatial coherence.The capabilities of the Hartmann wavefront sensor will be compared with experimental results from in-line X-ray Phase Contrast Tomography.

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Recent Progress in X-ray and Neutron Phase Imaging with Gratings

Cited by 22 publications

References 102 publications

EUV and Hard X-ray Hartmann Wavefront Sensing for Optical Metrology, Alignment and Phase Imaging

EUV and Hard X-ray Hartmann Wavefront Sensing for Optical Metrology, Alignment and Phase Imaging

Towards spatially resolved magnetic small-angle scattering studies by polarized and polarization-analyzed neutron dark-field contrast imaging

Phase-Contrast Tomography with X-ray Hartmann wavefront sensor

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