Scientific Reports (Oct 2021)

Free-moving Quantitative Gamma-ray Imaging

  • Daniel Hellfeld,
  • Mark S. Bandstra,
  • Jayson R. Vavrek,
  • Donald L. Gunter,
  • Joseph C. Curtis,
  • Marco Salathe,
  • Ryan Pavlovsky,
  • Victor Negut,
  • Paul J. Barton,
  • Joshua W. Cates,
  • Brian J. Quiter,
  • Reynold J. Cooper,
  • Kai Vetter,
  • Tenzing H. Y. Joshi

DOI
https://doi.org/10.1038/s41598-021-99588-z
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 14

Abstract

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Abstract The ability to map and estimate the activity of radiological source distributions in unknown three-dimensional environments has applications in the prevention and response to radiological accidents or threats as well as the enforcement and verification of international nuclear non-proliferation agreements. Such a capability requires well-characterized detector response functions, accurate time-dependent detector position and orientation data, a digitized representation of the surrounding 3D environment, and appropriate image reconstruction and uncertainty quantification methods. We have previously demonstrated 3D mapping of gamma-ray emitters with free-moving detector systems on a relative intensity scale using a technique called Scene Data Fusion (SDF). Here we characterize the detector response of a multi-element gamma-ray imaging system using experimentally benchmarked Monte Carlo simulations and perform 3D mapping on an absolute intensity scale. We present experimental reconstruction results from hand-carried and airborne measurements with point-like and distributed sources in known configurations, demonstrating quantitative SDF in complex 3D environments.