Optimizing Coded-Apertures for Depth-Resolved Diffraction

TL;DR

This paper explores how to optimize coded aperture designs for depth-resolved micro-diffraction imaging using synchrotron light, with empirical validation and insights for future improvements.

Contribution

It provides a systematic analysis of aperture specifications and scanning parameters for micro-coded aperture imaging, supported by experimental data.

Findings

Aperture size, thickness, and pattern significantly affect reconstruction quality.

Numerical experiments guide optimal aperture design choices.

Empirical data validates the effectiveness of proposed aperture configurations.

Abstract

Coded apertures, traditionally employed in x-ray astronomy for imaging celestial objects, are now being adapted for micro-scale applications, particularly in studying microscopic specimens with synchrotron light diffraction. In this paper, we focus on micro-coded aperture imaging and its capacity to accomplish depth-resolved micro-diffraction analysis within crystalline specimens. We study aperture specifications and scanning parameters by assessing characteristics like size, thickness, and patterns. Numerical experiments assist in assessing their impact on reconstruction quality. Empirical data from a Laue diffraction microscope at a synchrotron undulator beamline supports our findings. Overall, our results offer key insights for optimizing aperture design in advancing micro-scale diffraction imaging at synchrotrons. This study contributes insights to this expanding field and suggests significant advancements, especially when coupled with the enhanced flux anticipated from the global upgrades of synchrotron sources.