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3D isotope density measurements by energy-resolved neutron imaging

Adrian Losko, Sven C. Vogel

2022Scientific Reports27 citationsDOIOpen Access PDF

Abstract

Abstract Tools for three-dimensional elemental characterization are available on length scales ranging from individual atoms, using electrons as a probe, to micrometers with X-rays. However, for larger volumes up to millimeters or centimeters, quantitative measurements of elemental or isotope densities were hitherto only possible on the surface. Here, a novel quantitative elemental characterization method based on energy-resolved neutron imaging, utilizing the known neutron absorption cross sections with their ‘finger-print’ absorption resonance signatures, is demonstrated. Enabled by a pixilated time-of-flight neutron transmission detector installed at an intense short-pulsed spallation neutron source, for this demonstration 3.25 million state-of-the-art nuclear physics neutron transmission analyses were conducted to derive isotopic densities for five isotopes in 3D in a volume of 0.25 cm 3 . The tomographic reconstruction of the isotope densities provides elemental maps similar to X-ray microprobe maps for any cross section in the probed volume. The bulk isotopic density of a U-20Pu-10Zr-3Np-2Am nuclear transmutation fuel sample was measured, agrees well with mass-spectrometry and is evidence of the accuracy of the method.

Topics & Concepts

NeutronSpallationSpallation Neutron SourceIsotopeNeutron sourceNeutron stimulated emission computed tomographyCharacterization (materials science)Elemental analysisAbsorption (acoustics)Neutron generatorMaterials scienceNeutron scatteringPhysicsNuclear physicsNeutron cross sectionChemistryOpticsOrganic chemistryNuclear Physics and ApplicationsNuclear reactor physics and engineeringRadiation Detection and Scintillator Technologies
3D isotope density measurements by energy-resolved neutron imaging | Litcius