X-ray near-field ptychography for optically thick specimens

Marco Stockmar; Irene Zanette; Martin Dierolf; Bjoern Enders; Richard Clare; Franz Pfeiffer; Peter Cloetens; Anne Bonnin; Pierre Thibault

doi:10.1103/PhysRevApplied.3.014005

X-ray near-field ptychography for optically thick specimens

Marco Stockmar, Irene Zanette, Martin Dierolf, Bjoern Enders, Richard Clare, Franz Pfeiffer, Peter Cloetens, Anne Bonnin, Pierre Thibault

Chair of Biomedical Physics

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

Inline holography, like other lensless imaging methods, circumvents limitations of x-ray optics through an a posteriori phase-retrieval step. However, phase retrieval for optically thick, i.e., strongly absorbing and phase shifting, specimens remains challenging. In this paper, we demonstrate that near-field ptychography can be used to efficiently perform phase retrieval on a uranium sphere with a diameter of about 46 μm, which acts as an optically thick sample. This particular sample was not accessible by inline holography previously. The reconstruction is based on a statistical model and incorporates partial coherence by decomposing the illumination into coherent modes. Furthermore, we observe that phase vortices, which can occur as artifacts during the reconstruction, pose a greater challenge than in far-field methods. We expect that the methods described in this paper will allow production of reliable phase maps of samples which cannot be accessed by inline holography.

Original language	English
Article number	014005
Journal	Physical Review Applied
Volume	3
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevApplied.3.014005
State	Published - 21 Jan 2015

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abstract = "Inline holography, like other lensless imaging methods, circumvents limitations of x-ray optics through an a posteriori phase-retrieval step. However, phase retrieval for optically thick, i.e., strongly absorbing and phase shifting, specimens remains challenging. In this paper, we demonstrate that near-field ptychography can be used to efficiently perform phase retrieval on a uranium sphere with a diameter of about 46 μm, which acts as an optically thick sample. This particular sample was not accessible by inline holography previously. The reconstruction is based on a statistical model and incorporates partial coherence by decomposing the illumination into coherent modes. Furthermore, we observe that phase vortices, which can occur as artifacts during the reconstruction, pose a greater challenge than in far-field methods. We expect that the methods described in this paper will allow production of reliable phase maps of samples which cannot be accessed by inline holography.",

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AU - Stockmar, Marco

AU - Zanette, Irene

AU - Dierolf, Martin

AU - Enders, Bjoern

AU - Clare, Richard

AU - Pfeiffer, Franz

AU - Cloetens, Peter

AU - Bonnin, Anne

AU - Thibault, Pierre

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X-ray near-field ptychography for optically thick specimens

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