Nature Communications (Apr 2023)

Layered BiOI single crystals capable of detecting low dose rates of X-rays

  • Robert A. Jagt,
  • Ivona Bravić,
  • Lissa Eyre,
  • Krzysztof Gałkowski,
  • Joanna Borowiec,
  • Kavya Reddy Dudipala,
  • Michał Baranowski,
  • Mateusz Dyksik,
  • Tim W. J. van de Goor,
  • Theo Kreouzis,
  • Ming Xiao,
  • Adrian Bevan,
  • Paulina Płochocka,
  • Samuel D. Stranks,
  • Felix Deschler,
  • Bartomeu Monserrat,
  • Judith L. MacManus-Driscoll,
  • Robert L. Z. Hoye

DOI
https://doi.org/10.1038/s41467-023-38008-4
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 12

Abstract

Read online

Abstract Detecting low dose rates of X-rays is critical for making safer radiology instruments, but is limited by the absorber materials available. Here, we develop bismuth oxyiodide (BiOI) single crystals into effective X-ray detectors. BiOI features complex lattice dynamics, owing to the ionic character of the lattice and weak van der Waals interactions between layers. Through use of ultrafast spectroscopy, first-principles computations and detailed optical and structural characterisation, we show that photoexcited charge-carriers in BiOI couple to intralayer breathing phonon modes, forming large polarons, thus enabling longer drift lengths for the photoexcited carriers than would be expected if self-trapping occurred. This, combined with the low and stable dark currents and high linear X-ray attenuation coefficients, leads to strong detector performance. High sensitivities reaching 1.1 × 103 μC Gyair −1 cm−2 are achieved, and the lowest dose rate directly measured by the detectors was 22 nGyair s−1. The photophysical principles discussed herein offer new design avenues for novel materials with heavy elements and low-dimensional electronic structures for (opto)electronic applications.