Abstract
Accurate measurement of natural and anthropogenic radionuclide concentrations is of critical importance to end users in the nuclear sector to ensure correct classification prior to storage, recycling, reprocessing or disposal. Uncertainties in the characterisation of solid matrices and materials could lead to safety, quality and financial implications. Robust sample preparation methods are vital, in particular effective sample digestion, as under-estimated chemical yield recovery results in a corresponding under-estimation of activity levels. Borate fusion has been proven to effectively digest a range of complex sample matrices in the geosciences but is not used routinely elsewhere. In this study, we describe an automated procedure for borate fusion of multiple matrices encountered in nuclear decommissioning, containing diverse radionuclides over a range of activity concentrations. The impact of digestion flux, sample mass and sample to flux ratios are described, as well as the subsequent separation and measurement techniques. The results contribute to accurate and precise measurement of radionuclides in various matrices, as well as to characterisation of reference materials, providing greater confidence in nuclear industry programmes worldwide.
Highlights
There are currently 438 nuclear power plants in operation worldwide, with a further 149 that are, or soon will be, undergoing decommissioning [1]
This paper describes the development of automated borate fusion procedures for complete dissolution of a range of sample matrices in relation to reference material production, Naturally occurring radioactive material (NORM) characterisation and nuclear decommissioning
Fusion procedures have proven effective for the analysis of a range of radionuclides in solid matrices including titanium dioxide, sand, tuff, sediment, soil, cement, graphite and concrete
Summary
There are currently 438 nuclear power plants in operation worldwide, with a further 149 that are, or soon will be, undergoing decommissioning [1]. 13 nuclear power plants have been completely decommissioned worldwide, and lengthy timescales are required to complete the process, meaning technical experience is limited. The matrix of a NORM residue varies significantly depending on its industry of origin, and the activity concentrations of naturally occurring radionuclides (isotopes from the 238U, 235U and 232Th decay chains) can be enhanced through certain anthropogenic processes. Industries that undertake such processes need to adhere to regulations surrounding the storage, handling and disposal of such material
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