Near-perfect efficiency in X-ray phase microtomography

TL;DR

This paper introduces a novel X-ray microtomography setup that significantly improves detection efficiency and contrast visibility, enabling high-resolution, dose-efficient imaging of biological tissues in their native state.

Contribution

A new combined system using an X-ray waveguide, structured phase modulator, and photon-counting detector achieves near-theoretical limits in visibility and efficiency for microtomography.

Findings

Achieves 95% modulation visibility

Reaches 98% quantum efficiency

Enables dose-efficient imaging of native tissues

Abstract

X-ray microtomography at synchrotron sources is fundamentally limited by the high radiation dose applied to the samples, which restricts investigations to non-native tissue states and thereby compromises the biological relevance of the resulting data. The limitation stems from inefficient indirect detection schemes that require prolonged exposures. Efforts to extract additional contrast through multimodal techniques, like modulation-based imaging, worsen the problem by requiring multiple tomographic scans. In addition, the techniques suffer from low modulator pattern visibility, which reduces measurement efficiency and sensitivity. We address both the detection efficiency and modulation visibility challenges using a novel setup that combines an X-ray waveguide, a structured phase modulator, and a photon-counting detector. Our approach simultaneously achieves near-theoretical limits in both visibility (95%) and quantum efficiency (98%), thereby enabling dose-efficient multimodal microtomography at single-micrometer resolution. This advance will enable new classes of experiments on native-state biological specimens with the potential to advance biomedical research, disease diagnostics, and our understanding of tissue structure in physiological environments.