Calibration of Solid State Nuclear Track Detectors CR-39 for radon study in a high concentration underground mines

Laura Takahashi; Talita Santos; Bárbara Correa; Rose Mary Pinheiro; Maria Ângela Menezes; Zildete Rocha

doi:10.15392/bjrs.v9i1A.1533

Authors

Laura Takahashi Centro de Desenvolvimento da Tecnologia Nuclear (CDTN/CNEN)
Talita Santos Universidade Federal de Minas Gerais (UFMG) - Faculdade de Medicina, Departamento de Anatomia e Imagem
Bárbara Correa Universidade Federal de Minas Gerais (UFMG) - Faculdade de Medicina, Departamento de Anatomia e Imagem
Rose Mary Pinheiro Centro de Desenvolvimento da Tecnologia Nuclear (CDTN/CNEN)
Maria Ângela Menezes Centro de Desenvolvimento da Tecnologia Nuclear (CDTN/CNEN)
Zildete Rocha Centro de Desenvolvimento da Tecnologia Nuclear (CDTN/CNEN)

DOI:

https://doi.org/10.15392/bjrs.v9i1A.1533

Keywords:

radon, CR-39, underground mines.

Abstract

The Brazilian National Commission for Nuclear Energy (CNEN) establishes a reference level of 1000 Bq m^-3of radon concentration in underground mines. Solid State Nuclear Track Detectors – SSNTD is considered the main method of analysis in radon research. The methods and instrumentation used to determine radon concentration needs to be validated by calibration to ensure reliable results. This work aims to determine the calibration factor of CR-39 detectors exposed to well known radon concentrations produced in closed systems by sources of Ra-226 with activities of 3.379 kBq and 0.483 kBq, which are NISTS sources of activities and emanation factors. The detectors were exposed to six different levels of exposure. The conversion factor between tracks density and exposure obtained was K = 52.028 ± 0.752 [(tracks density.cm^-2)/(kBq.d.m^-3)]. As object of application of this work, mines were chosen with high radon concentrations reported by Santos (2015) in special a pegmatite mine located in the northwest of Minas Gerais. This mine presented radon concentration much higher than the recommended by the Brazilian national standard NN.CNEN.4.01, up to 7384 ± 517 Bq m^-3.

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References

BONOTTO, D. M. Radioatividade nas águas: Da Inglaterra ao Guarani. São Paulo, 2004.

DANIS, A.; ONCESCU, M.; CIUBOTARIU, M. System for calibration of track detectors use in gaseous and solid alpha radionuclides monitoring. Radiation Measurements, v. 34, p.155- 159, 2001.

RIO. DOCE, A. P. C. Determinação da taxa de exalação de 222Rn em materiais de constru-ção. Master's Dissertation of Universidade Federal do Rio de Janeiro, UFRJ-COPPE, 1997.

MIRANDA, V.F.E. Estudo dos Níveis da Emanação de 222Rn Presentes nos Materiais Radi-oativos de Ocorrência Natural – NORM. Master's Dissertation of Engenharia Nuclear, Instituto Alberto Luiz Coimbra, Universidade Federal do Rio de Janeiro, 2009.

SANTOS, T. O.; ROCHA, Z.; CRUZ, P.; GOUVEA, V. A.; SIQUEIRA, J. B.; OLIVEIRA, A. H. Radon Dose Assessment in Underground Mines in Brazil. Radiation Protection Dosimetry, v. 160, p. 120-123, 2014.

BANJANAC, R.; DRAGIĆ. A.; GRABEŽ, B.; JOKOVIĆ, D.; MARKUSHEV, D.; PANIĆ, B.; UDOVIČIĆ, V.; ANIČIN, I. Indoor Radon Measurements by Nuclear Track Detector: Applications in Secondary School. Physics, Chemistry and Technology, v, 4, n. 1, p. 93-100, 2006.

CIGNA, A. A. Radon in Caves. Internacional Journal of Speleolog, v. 34, p. 1-18, 2005.

ICRP – International Commission on Radiological Protection. Lung cancer risk from indoor exposure to radon and daughters. ICRP Publication 50. Pergamon Press, Oxford, 1987.

Manual da OMS. Radônio em ambientes internos – uma perspectiva de saúde pública. Insti-tuto de radioproteção e dosimetria, 1º Edição, 2016.

OPAS – Organização Pan-Americana de Saúde. Site. 2018. Disponível em https://www.paho.org/bra/index.php?option=com_content&view=article&id=5588:folha-informativa-cancer&Itemid=1094. Acesso em 28 de julho de 2020.

ICRP – International Commission on Radiological Protection. Protection Against Radon-222 at home and at work. ICRP Publication 50. Pergamon Press, Oxford, 1994.

SANTOS, T.O.; ROCHA, Z.; VASCONCELOS, V.; LARA, E.G.; PALMIERI, L.E.H.; CRUZ. P.; GOUVEA, V.A.; SIQUEIRA, J.B.; OLIVEIRA, H.A. Evaluation of Natural Radionuclides in Brazilian Underground Mines. Radiation Physics and Chemistry. v. 116, p.377-380, 2015.

ICRP – International Commission on Radiological Protection. Radiation protection of workers in mines. ICRP Publication 47. Oxford: Pergamon Press, 1986.

PINTO, L.C.M. Quantikov: uma analisador microestrutural para o ambiente Windows, São Paulo, 1996.

UNSCEAR – United Nations Scientific Committee on the Effects of Atomic Radiation. Sources and Effects of Ionization Radiation. Vol. I – Sources, Report to General Assembly, with Scientific Annexes. United Nations, New York, 2000.