Phase-sensitive x-ray ghost imaging

TL;DR

This paper introduces a novel phase-sensitive x-ray ghost imaging technique that combines high spatial resolution and phase contrast, enabling low-dose, high-fidelity imaging suitable for various high-energy probes.

Contribution

It presents a new method that integrates ghost imaging with phase contrast, achieving efficient, high-resolution, low-dose x-ray imaging with potential for practical tomography and other probes.

Findings

Achieves high-fidelity phase-contrast x-ray ghost images

Demonstrates scalability to large fields of view and high energies

Applicable to other phase-sensitive imaging modalities

Abstract

Imaging with hard x-rays is an invaluable tool in medicine, biology, materials science, and cultural heritage. Propagation-based x-ray phase-contrast imaging and tomography have been mostly used to resolve micrometer-scale structures inside weakly absorbing objects as well as inside dense specimens. Indirect x-ray detection has been the key technology to achieve up to sub-micrometer spatial resolutions, albeit inefficiently and hence at the expense of increased radiation dose to the specimen. A promising approach to low-dose imaging and high spatial resolution even at high x-ray energies is ghost imaging, which could use single-pixel, yet efficient direct x-ray detectors made of high-density materials. However, phase contrast has not yet been realised with x-ray ghost imaging. We present an approach which exploits both the advantages of x-ray ghost imaging and the high sensitivity of phase-contrast imaging. In comparison with existing techniques, our method is efficient and achieves high-fidelity x-ray ghost images with phase contrast, accurate density resolution and dramatically higher spatial resolution. The method is scalable to practical tomography with large fields of view, micrometer spatial resolution, and with high-energy x-rays above 100 keV. It is also applicable to other phase-sensitive imaging techniques and with other probes such as neutrons, alpha rays, and muons, for which high spatial resolution detectors are limited or even not available.