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Uncertainty quantification applied to the radiological characterization of radioactive waste

This paper describes the process adopted at the European Organization for Nuclear Research (CERN) to quantify uncertainties affecting the characterization of very-low-level radioactive waste. Radioactive waste is a by-product of the operation of high-energy particle accelerators. Radioactive waste m...

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Autores principales: Zaffora, B, Magistris, M, Saporta, G, Chevalier, J -P
Lenguaje:eng
Publicado: 2017
Materias:
Acceso en línea:https://dx.doi.org/10.1016/j.apradiso.2017.06.001
http://cds.cern.ch/record/2708127
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author Zaffora, B
Magistris, M
Saporta, G
Chevalier, J -P
author_facet Zaffora, B
Magistris, M
Saporta, G
Chevalier, J -P
author_sort Zaffora, B
collection CERN
description This paper describes the process adopted at the European Organization for Nuclear Research (CERN) to quantify uncertainties affecting the characterization of very-low-level radioactive waste. Radioactive waste is a by-product of the operation of high-energy particle accelerators. Radioactive waste must be characterized to ensure its safe disposal in final repositories. Characterizing radioactive waste means establishing the list of radionuclides together with their activities. The estimated activity levels are compared to the limits given by the national authority of the waste disposal. The quantification of the uncertainty affecting the concentration of the radionuclides is therefore essential to estimate the acceptability of the waste in the final repository but also to control the sorting, volume reduction and packaging phases of the characterization process. The characterization method consists of estimating the activity of produced radionuclides either by experimental methods or statistical approaches. The uncertainties are estimated using classical statistical methods and uncertainty propagation. A mixed multivariate random vector is built to generate random input parameters for the activity calculations. The random vector is a robust tool to account for the unknown radiological history of legacy waste. This analytical technique is also particularly useful to generate random chemical compositions of materials when the trace element concentrations are not available or cannot be measured. The methodology was validated using a waste population of legacy copper activated at CERN. The methodology introduced here represents a first approach for the uncertainty quantification (UQ) of the characterization process of waste produced at particle accelerators.
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language eng
publishDate 2017
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spelling oai-inspirehep.net-17773172020-03-06T15:48:02Zdoi:10.1016/j.apradiso.2017.06.001http://cds.cern.ch/record/2708127engZaffora, BMagistris, MSaporta, GChevalier, J -PUncertainty quantification applied to the radiological characterization of radioactive wasteOtherThis paper describes the process adopted at the European Organization for Nuclear Research (CERN) to quantify uncertainties affecting the characterization of very-low-level radioactive waste. Radioactive waste is a by-product of the operation of high-energy particle accelerators. Radioactive waste must be characterized to ensure its safe disposal in final repositories. Characterizing radioactive waste means establishing the list of radionuclides together with their activities. The estimated activity levels are compared to the limits given by the national authority of the waste disposal. The quantification of the uncertainty affecting the concentration of the radionuclides is therefore essential to estimate the acceptability of the waste in the final repository but also to control the sorting, volume reduction and packaging phases of the characterization process. The characterization method consists of estimating the activity of produced radionuclides either by experimental methods or statistical approaches. The uncertainties are estimated using classical statistical methods and uncertainty propagation. A mixed multivariate random vector is built to generate random input parameters for the activity calculations. The random vector is a robust tool to account for the unknown radiological history of legacy waste. This analytical technique is also particularly useful to generate random chemical compositions of materials when the trace element concentrations are not available or cannot be measured. The methodology was validated using a waste population of legacy copper activated at CERN. The methodology introduced here represents a first approach for the uncertainty quantification (UQ) of the characterization process of waste produced at particle accelerators.oai:inspirehep.net:17773172017
spellingShingle Other
Zaffora, B
Magistris, M
Saporta, G
Chevalier, J -P
Uncertainty quantification applied to the radiological characterization of radioactive waste
title Uncertainty quantification applied to the radiological characterization of radioactive waste
title_full Uncertainty quantification applied to the radiological characterization of radioactive waste
title_fullStr Uncertainty quantification applied to the radiological characterization of radioactive waste
title_full_unstemmed Uncertainty quantification applied to the radiological characterization of radioactive waste
title_short Uncertainty quantification applied to the radiological characterization of radioactive waste
title_sort uncertainty quantification applied to the radiological characterization of radioactive waste
topic Other
url https://dx.doi.org/10.1016/j.apradiso.2017.06.001
http://cds.cern.ch/record/2708127
work_keys_str_mv AT zafforab uncertaintyquantificationappliedtotheradiologicalcharacterizationofradioactivewaste
AT magistrism uncertaintyquantificationappliedtotheradiologicalcharacterizationofradioactivewaste
AT saportag uncertaintyquantificationappliedtotheradiologicalcharacterizationofradioactivewaste
AT chevalierjp uncertaintyquantificationappliedtotheradiologicalcharacterizationofradioactivewaste