Brazilian clays for environmental solutions applied to radioactive waste management

Autores

  • Gabriel Gonzalo Machado Entrepreneurship project leader at Argilos
  • Victoria Krupskaya Institute of Geology of Ore Deposits, Petrography, Mineralogy and Geochemistry Russian Academy of Science (IGEM RAS)
  • Sergey V Zakusin Russian Academy of Sciences, Institute of Geology of Ore Deposits, Petrography, Mineralogy and Geochemistry Staromonetny Pereulok, 35 – 119017 Moscow, Russia
  • Julio HARADA ARGILOS
  • Rodrigo Papai de Souza IPT
  • Leandro Goulart Araujo IPEN/CNEN
  • Denise Crocce Espinosa USP
  • Edy L.T. Montalvan USP
  • Henrique Kahn USP
  • Roberto Vicente IPEN/CNEN
  • Sabine Guilhen IPEN/CNEN

DOI:

https://doi.org/10.15392/bjrs.v9i1A.1539

Palavras-chave:

CLAYS, SMECTITE, TENORM, CESIUM, ADSORPTION, EBS

Resumo

Clays have been adopted in most nuclear waste producing countries as a key constituent in engineered barrier systems for final disposal facilities at all levels of radioactive wastes (LILW-SL, LILW-LL, and HLW). The following study presents a thorough characterization upon five Brazilian clay-rich deposits, mostly smectite bearing clays, aiming to evaluate their expected performance as barrier under the conditions associated to a Low and Intermediate Level Waste Repository; being the former a matter of national strategic interest. Samples coming from the Brazilian states of Paraná, Bahia, Paraíba, and Maranhão were treated and analyzed by means of X-Ray diffraction as main technique, and complemented by FTIR, LALLS, XRF, and SEM-EDS, in order to establish the mineralogical composition, particle size distribution, and chemical composition. Moreover, several standard clay treatments over the <1 μm size fraction were carried out to reveal information regarding layer charge, major interlayer cations, unit formula and other crystal features of smectite species present in a mineralogical assembly, aiming to provide information for the construction of a molecular model over which would be realistic to simulate the diffusion of radionuclides. Results obtained on 133Cs adsorption experiments indicate that mineralogical composition would probably be the single most influential factor controlling transport capacity of positively charged radionuclides in the current setup. The composition is especially expressed in terms of smectite contents, favoring montmorillonite rich materials containing majorly Na+ as compensating cation in interlayer position. All tested samples can be considered as suitable candidates to be used in the design of final destination storage for nuclear waste. Thus, efficiency on 133Cs adsorption trials also indicate that these materials could have potential uses as sorptive matrices (Sorbents) for water treatment of radionuclide polluted waters such as TENORM waste waters. However, these trends are yet to be contrasted against hydraulic conductivity measurements and swelling pressure in order to have a more comprehensive perspective of this clayey prospects as barrier enhanced layer; aligned to the multilayer barrier system approach for nuclear waste management.

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Biografia do Autor

  • Gabriel Gonzalo Machado, Entrepreneurship project leader at Argilos
    Mining engineer specialized in Clays & Clay minerals

Referências

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Publicado

30-04-2021

Edição

v. 9 n. 1A (2021)

Seção

The Meeting on Nuclear Applications (ENAN) 2019

Licença

Direitos autorais (c) 2021 Brazilian Journal of Radiation Sciences

Creative Commons License

Este trabalho está licenciado sob uma licença Creative Commons Attribution 4.0 International License.

Declaro que o presente artigo é original, não tendo sido submetido à publicação em qualquer outro periódico nacional ou internacional, quer seja em parte ou em sua totalidade. Declaro, ainda, que uma vez publicado na revista Brazilian Journal of Radiation Sciences, editada pela Sociedade Brasileira de Proteção Radiológica, o mesmo jamais será submetido por mim ou por qualquer um dos demais co-autores a qualquer outro periódico. Através deste instrumento, em meu nome e em nome dos demais co-autores, porventura existentes, cedo os direitos autorais do referido artigo à Sociedade Brasileira de Proteção Radiológica, que está autorizada a publicá-lo em meio impresso, digital, ou outro existente, sem retribuição financeira para os autores.

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Como Citar

Brazilian clays for environmental solutions applied to radioactive waste management. Brazilian Journal of Radiation Sciences, Rio de Janeiro, Brazil, v. 9, n. 1A, 2021. DOI: 10.15392/bjrs.v9i1A.1539. Disponível em: https://www.bjrs.org.br/revista/index.php/REVISTA/article/view/1539. Acesso em: 20 jul. 2025.