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Characterisation of ‘hot’ particles using nano- and micro-focus synchrotron X-ray techniques

DOI: 10.22443/rms.mmc2021.169 DOI Help

Authors: Joyce W. L. Ang (University of Helsinki) , Kazuya Morooka (Kyushu University) , Eitaro Kurihara (Kyushu University) , William R. Bower (University of Helsinki) , J. Frederick W. Mosselmans (Diamond Light Source) , Julia Parker (Diamond Light Source) , Satoshi Utsunomiya (Kyushu University) , Gareth T. W. Law (University of Helsinki)
Co-authored by industrial partner: No

Type: Conference Paper
Conference: Microscience Microscopy Congress 2021
Peer Reviewed: No

State: Published (Approved)
Published: July 2021

Abstract: Radioactive ‘hot’ particles can be deposited in the environment as a result of illicit activities, nuclear accidents (e.g., Chernobyl, Fukushima), weapons use, mining, and/or nuclear waste disposal. Understanding the long-term behaviour of such materials in the environment is important for understanding risk and environmental impact, and for designing remediation strategies. However, mechanistic knowledge of hot particle alteration processes, reaction products, and radionuclide speciation are limited, especially at finely resolved spatial scales. In this talk, we provide two case-studies that detail how micro- to nano-focus synchrotron X-ray techniques can be used as part of an analytical “tool kit” to fully characterise nuclear industry born hot particles. In turn, this data can inform safety assessments and clean-up / decommissioning efforts at radioactively contaminated sites. In both case-studies, we examine highly radioactive micro-particles that were found in soil samples taken from nuclear exclusion zone that surrounds the Fukushima Daiichi Nuclear Power Plant (FDNPP). These particles were emitted from the damaged FDNPP reactors during the 2011 accident. Recent work by our group [1, 2] has shown that these particles are common forms of contamination in the nuclear exclusion zone, but the possible environmental and human-health impacts of the particles are not yet known. Recent work [3, 4] on Diamond Light Source Beamlines I18 (micro-focus X-ray spectroscopy) and I14 (Hard X-ray nanoprobe), and the Swiss Light Source micro-XAS Beamline, has permitted detailed chemical characterisation of these challenging materials. In case study 1, we will present micro-focus data that describes the speciation of actinide elements in whole FDNPP hot particles [3]. The data includes the first speciation information for plutonium released from the damaged FDNPP reactors. In case study 2, we present nano-probe characterisation of recently discovered hot particles derived from FDNPP reactor Unit 1 [4]. These particles have the highest ever recorded 134+137Cs radioactivities for particles released from the FDNPP. In our work, FIB sectioning of the particles permitted detailed SIMS, electron microscopy, and hard X-ray nano-probe analysis of the particles. In particular, combined electron-microscopy and synchrotron-based nano-focus XRF and XRD analyses were used to characterise the particles (e.g., Figure 1). For both case studies we will provide an overview of sample preparation, analysis considerations, and discuss how the results inform management of the FDNPP legacy.

Subject Areas: Materials, Environment

Instruments: I14-Hard X-ray Nanoprobe , I18-Microfocus Spectroscopy

Other Facilities: micro-XAS at Swiss Light Source

Added On: 27/09/2021 10:20

Discipline Tags:

Earth Sciences & Environment Natural disaster Desertification & Pollution Materials Science Radioactive Materials

Technical Tags:

Spectroscopy Microfocus Spectroscopy