English

Fluorescence intensity correlations enable 3D imaging without sample rotations

Optics 2025-10-30 v2

Abstract

Lensless X-ray imaging provides element-specific nanoscale insights into thick samples beyond the reach of conventional light and electron microscopy. Coherent diffraction imaging (CDI) methods, such as ptychographic tomography, can recover three-dimensional (3D) nanoscale structures but require extensive sample rotation, adding complexity to experiments. X-ray elastic-scattering patterns from a single sample orientation are highly directional and provide limited 3D information about the structure. In contrast to X-ray elastic scattering, X-ray fluorescence is emitted mostly isotropically. However, first-order spatial coherence has traditionally limited nanoscale fluorescence imaging to single-crystalline samples. Here, we demonstrate that intensity correlations of X-ray fluorescence excited by ultrashort X-ray pulses contain 3D structural information of non-periodic, stationary objects. In our experiment, we illuminated a vanadium foil within a sub-200 nm X-ray laser beam focus. Without changing the sample orientation, we recorded 16 distinct specimen projections using detector regions covering different photon incidence angles relative to the X-ray free-electron laser (FEL) beam. The projections varied systematically as the fluorescing volume was translated along an astigmatism, confirming that FEL-induced fluorescence reflects real-space structural changes. Our results establish a new approach for lensless 3D imaging of non-periodic specimens using fluorescence intensity correlations, with broad implications for materials science, chemistry, and nanotechnology.

Keywords

Cite

@article{arxiv.2510.24386,
  title  = {Fluorescence intensity correlations enable 3D imaging without sample rotations},
  author = {Robert G. Radloff and Felix F. Zimmermann and Siqi Li and Stephan Kuschel and Anatoli Ulmer and Yanwen Sun and Takahiro Sato and Peihao Sun and Johann Haber and Diling Zhu and Miklós Tegze and Gyula Faigel and Matthew R. Ware and Jordan T. O'Neal and Jumpei Yamada and Taito Osaka and Robert Zierold and Carina Hedrich and Dimitrios Kazazis and Yasin Ekinci and Makina Yabashi and Ichiro Inoue and Andrew Aquila and Meng Liang and Agostino Marinelli and Tais Gorkhover},
  journal= {arXiv preprint arXiv:2510.24386},
  year   = {2025}
}
R2 v1 2026-07-01T07:09:32.650Z