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Rieger J, Meyer P, Pelzer G, et al. Designing the phase grating for Talbot-Lau phase-contrast imaging systems: a simulation and experiment study. Opt Express. 2016;24(12):13357-64doi: 10.1364/OE.24.013357.
Rieger, J., Meyer, P., Pelzer, G., Weber, T., Michel, T., Mohr, J., & Anton, G. (2016). Designing the phase grating for Talbot-Lau phase-contrast imaging systems: a simulation and experiment study. Optics express, 24(12), 13357-64. https://doi.org/10.1364/OE.24.013357
Rieger, Jens, et al. "Designing the phase grating for Talbot-Lau phase-contrast imaging systems: a simulation and experiment study." Optics express vol. 24,12 (2016): 13357-64. doi: https://doi.org/10.1364/OE.24.013357
Rieger J, Meyer P, Pelzer G, Weber T, Michel T, Mohr J, Anton G. Designing the phase grating for Talbot-Lau phase-contrast imaging systems: a simulation and experiment study. Opt Express. 2016 Jun 13;24(12):13357-64. doi: 10.1364/OE.24.013357. PMID: 27410353.
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Opt Express. 2016 Jun 13;24(12):13357-64. doi: 10.1364/OE.24.013357.

Designing the phase grating for Talbot-Lau phase-contrast imaging systems: a simulation and experiment study.

Optics express

Jens Rieger, Pascal Meyer, Georg Pelzer, Thomas Weber, Thilo Michel, Jürgen Mohr, Gisela Anton

PMID: 27410353 DOI: 10.1364/OE.24.013357

Abstract

The performance of a Talbot-Lau interferometer depends to a great extent on its visibility. This means, to obtain high quality phase-contrast and dark-field images a high visibility is mandatory. Several parameters influence the visibility of such a system, like for example the x-ray spectrum, the inter-grating distances or the parameters of the three gratings. In this multidimensional space, wave field simulations help to find the optimal combination of the grating specifications to construct a setup with a high visibility while retaining a fixed angular sensitivity. In this work we specifically analyzed the influence of the G1 grating duty cycle in simulations and experiments. We show that there is a lot of room for improvement by varying the duty cycle of the phase-shifting grating G1. As a result, by employing a third-integer duty cycle we can increase the visibility to up to 53 % in a laboratory setup with a polychromatic spectrum. The achieved visibility is more than two times higher compared to the result with a standard-type setup. This visibility gain allows a dose reduction by a factor of 5 preserving the same image quality.

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