Gamma radiation dose rate measurements in granite quarries and schools in two mountainous towns in Benin

Autores

  • Mahougnon Zinsou University of Abomey-Calavi (UAC), URGB/LETIA/EPAC/UAC & URRMH/LARBA/EPAC/UAC, Republic of Benin
  • Codjo Roland HOUESSOUVO University of Abomey-Calavi (UAC), URGB/LETIA/EPAC/UAC & URRMH/LARBA/EPAC/UAC, Republic of Benin
  • Naivo RABESIRANANA University of Antananarivo, Republic of Madagascar
  • Sétchéou Rodrigue ALLODJI University of Paris-Saclay, France
  • Daton MEDENOU University of Abomey-Calavi (UAC), URGB/LETIA/EPAC/UAC & URRMH/LARBA/EPAC/UAC, Republic of Benin
  • Julien DOSSOU University of Abomey-Calavi (UAC), URGB/LETIA/EPAC/UAC & URRMH/LARBA/EPAC/UAC, Republic of Benin
  • Bertin GBAGUIDI University of Abomey-Calavi (UAC), URGB/LETIA/EPAC/UAC & URRMH/LARBA/EPAC/UAC, Republic of Benin
  • Elder Magalhaes De Souza International Atomic Energy Agency, Vienna, Austria
  • Guy MENSAH National Institute for Agricultural Research of Benin, Republic of Benin

DOI:

https://doi.org/10.15392/2319-0612.2024.2517

Palavras-chave:

natural radionuclide, public health, radiometer, effective dose, granite crushers

Resumo

The radiation protection of the public against ionizing radiation emitted by natural sources from the earth's crust is a public health issue. The aim of this study, carried out in the granite quarries and schools of the towns of Glazoue and Dassa-zoume, is to assess the population's external exposure to ambient gamma radiation emitted by natural radionuclides (238U, 232Th, 40K, etc.). It covered the dry season from January to April 2021. 12 quarries and 39 schools were included in the study. 510 ambient gamma dose equivalent rates were carried out during the study period with the radiometer and the portable NaI gamma detector simultaneously. For comparison purposes, ten (10) measurements were taken in the city of Cotonou. Gamma dose equivalent rates in the quarries of both cities ranged from 0.11 to 0.40 µSv/h, with an average of 0.255 µSv/h. Those for primary and secondary schools vary from 0.08 to 0.40 µSv/h, with an average of 0.24 µSv/h. The average dose equivalent rate recorded at Cotonou is is 0.045 µSv/h. The effective dose for a resident crusher ranges from 1.10 to 2.80 mSv/yr, with an average of 2.10 mSv/yr. Those for non-resident crushers range from 0.6 to 1.4 mSv/yr. Those for schools range from 0.144 mSv/yr to 0.432 mSv/yr, with an average of 0.252 mSv/yr. The effective dose obtained for granite crushers is higher than the value mentioned in the 2008 UNSCEAR report for outdoors and indoors exposure to terrestrial and cosmic radiation, which is equal to 0.87 mSv/yr.

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Referências

Zinsou M.B. Etude des anomalies chromosomiques radioinduites dans les lymphocytes des concasseurs de pierres granitiques de la carrière d’Itchédoun à GLAZOUE au Bénin (EACRLCIG-Bénin). 2014. Université d’Abomey-Calavi (UAC). Ecole Polytechnique d’Abomey-Calavi (EPAC). Mémoire de Master en Imagerie Médicale et Radiobiologie. P94.

Dossou J., Zinsou M. B., Abinda G.M., Aballo S., Ogoubi C., Laleye A., Fourn L., Loko F. S., Mensah G. A. Anomalies chromosomiques induites dans les lymphocytes des concasseurs de roche granitique de la carrière d’Itchédoun à Glazoué au centre du Bénin. 2014. Email : juju_dos@yahoo.fr.

AIEA. Radioprotection et sûreté des sources de rayonnements, Normes fondamentales internationales de sûreté. 2014. Collection Normes de sûreté de l’AIEA n° GSR Partie 3, Vienne (2014).

COMMISSION INTERNATIONALE DE PROTECTION RADIOLOGIQUE, Recommandations 2007 de la Commission internationale de protection radiologique, Publication 103 de la CIPR, IRSN (2009).

INTERNATIONAL COMMISSION ON RADIOLOGICAL PROTECTION. Lung Cancer Risk from Radon and Progeny and Statement on Radon. 2010. ICRP Publication 115, Elsevier.

LABORATOIRE NATIONAL HENRI BECQUEREL. Mini Table of Radionuclides. 2015. ISBN: 978-2-7598-1198-4. EDP Sciences 2015.

Delacroix D., Guerre J.P., Leblanc P. Guide pratique Radionucléides & Radioprotection : Manuel pour la manipulation de substances radioactives dans les laboratoires de faible et moyenne activité. 2006. Deuxième édition. EDP SCIENCES. Vol. 39, numéro spécial. Commissariat à l’Energie Atomique 2006. ISBN : 2-86883-864-2.

UNITED NATIONS. Sources and Effects of Ionizing Radiation (Report to the General Assembly), Scientific Committee on the Effects of Atomic Radiation (UNSCEAR). 2008. Table 6 and 12. UN. New York.

Anjos R.M., Ayub J.J., Cid A.S., Cardoso R., Lacerda T. External gamma-ray dose rate and radon concentration in indoor environments covered with Brazilian granites. 2011. E-mail address: meigikos@if.uff.br. doi:10.1016/j.jenvrad.2011.06.001.

Lespukh E., Stegnar P., Yunusov M., Tilloboev H., Zyazev G., Kayukov P., Hosseini A., Strømman G., Salbu B. Assessment of the radiological impact of gamma and radon dose rates at former U mining sites in Tajikistan. 2013. Email : stegnar@gmail.com , peter.stegnar@ijs.si. http://dx.doi.org/10.1016/j.jenvrad.2013.07.019.

Takoukam S. S. D., Saïdou., Tokonami S., HosodaM., Suzuki T., Kudo H., Bouba O. Simultaneous measurements of indoor radon and thoron and inhalation dose assessment in Douala City, Cameroon. 2019. Isotopes in Environmental and Health Studies. https://doi.org/10.1080/10256016.2019.1649258.

Zinsou M. B., Idjiwole F., Rabesiranana N., Dossou J., Mensah G. A., Medenou D. Techniques de mesure de l'exposition naturelle due au radon : Synthèse bibliographique. 2023. Bulletin de la Recherche Agronomique du Bénin (BRAB). Juin 2023 - Volume 33 - Numéro 03. Email : mahougnonbonifacezinsou@yahoo.fr.

Vaupotic J., Sikovec M., Kobal I. (2000). Systematic indoor radon and gamma-ray measurements in slovenian schools. E-mail : janja.vaupotic@ijs.si.

Vaupotic J., Bezek M., Ka´va´si N., Ishikawa T., Yonehara H., Tokonami S. (2012). Radon and thoron doses in kindergartens and elementary schools. DOI : 10.1093/rpd/ncs232. E-mail : janja.vaupotic@ijs.si.

Oikawa S., Kanno N., Sanada T., Abukawa J., Higuchi H. A survey of indoor workplace radon concentration in Japan. 2005. DOI : 10.1016/j.jenvrad.2005.12.001. e-mail : s-oikawa@jcac.or.jp.

Clouvas A., Takoudis G., Xanthos S., Potiriadis C., Kolovou M. Indoor radon measurements in areas of northern greece with relatively high indoor radon concentrations. 2009. DOI : 10.1093/rpd/ncp154. E-mail : clouvas@eng.auth.gr.

Ciolini R. and Mazed D. Indoor radon concentration in geothermal areas of central Italy. 2010. DOI : 10.1016/j.jenvrad.2010.04.012. e-mail : r.ciolini@ing.unipi.it.

Obed R.I., Ademola A.K., Vascotto M., Giannini G. Radon measurements by nuclear track detectors in secondary schools in Oke-Ogun region, Nigeria. 2011. DOI : 10.1016/j.jenvrad.2011.06.012. E-mail : rachelobed@yahoo.com.

Bochicchio F., Žunić Z. S., Carpentieri C., Antignani S., Venoso G., Carelli V., Cordedda C., Veselinović N., Tollefsen T., Bossew P. Radon in indoor air of primary schools: a systematic survey to evaluate factors affecting radon concentration levels and their variability. 2013. DOI : 10.1111/ina.12073. e-mail : francesco.bochicchio@iss.it.

Bossew P., Zunic Z.S., Stojanovska Z., Tollefsen T., Carpentieri C., Veselinovic N., Komatina S., Vaupotic J., Simovic R.D., Antignani S., Bochicchio F. (2013). Geographical distribution of the annual mean radon concentrations in primary schools of Southern Serbia : application of geostatistical methods. http://dx.doi.org/10.1016/j.jenvrad.2013.09.015. E-mail : pbossew@bfs.de , peter.bossew@reflex.at.

GBOHAIDA V., AGBANGNAN D. C. P., NGOSSANGA M.B., MEDOATINSA S.E., DOVONON L.F.C., D. Valentin WOTTO D.V., AVLESSI F., SOHOUNHLOUE D.C.K. Etude de la qualité physico-chimique de l’eau de boisson dans deux localités du Bénin : Cotonou et Dassa-Zoumè. 2016. Int. J. Biol. Chem. Sci. 10(1): 422-434, February 2016. E-mail: pascal.agbangnan@uac.bj, cokou2005@yahoo.fr. http://ajol.info/index.php/ijbcs http://indexmedicus.afro.who.int.

Awo-Affouda U. Projet d’AEP des villes de Savè, Dassa-zoumè, Glazoué, Savalou à partir des eaux de surface. 2016. p.97.

Saïdou., Tokonami S., Hosoda M., Tchuente S. Y. F., Nkoulou N., Emmanuel J., Naofumi A., Modibo O.B., Penaye J. Natural radiation exposure to the public in the uranium bearing region of Poli, Cameroon: From radioactivity measurements to external and inhalation dose assessment. 2019. https://doi.org/10.1016/j.gexplo.2019.106350. E-mail: saidous2002@yahoo.fr.

Modibo O. B., Saïdou., Nkoulou N., Emmanuel J., Suzuki T., Kudo H., Hosoda M., Owono L. C. O. and Tokonami S. Occupational Natural Radiation Exposure at the Uranium Deposit of Kitongo, Cameroon. 2019. E-mail: saidous2002@yahoo.fr. DOI : 10.3769/radioisotopes.68.621.

Kall B., Tombo T., Rasolonirina M., Rabesiranana N., Rambolamanana G. Contribution à l’étude de dose due à la radioactivité gamma du sol sur la rive de la baie des Français, Antsiranana, Madagascar. 2015. DOI : 10.4314/AFSCI. V11I1.

Bineng G. S., Saïdou., Hosoda M., Siaka Y., Akata N., Talla S. F., Abiama P., Tokonami S. Exposition du public aux rayonnements externes à l’aide de la méthode d’enquête embarquée dans la région contenant de l’uranium et du thorium de Lolodorf, Cameroun. 2020.

Nkoulou N., Emmanuel. J., Talla S. F., Bineng G. S., Manga A., Siaka Y., Saïdou. Mesures de la radioactivité naturelle dans le sol, dose externe et évaluation des risques radiologiques dans la région contenant de l’uranium et du thorium de Lolodorf, Cameroun. 2018. DOI:10.3769/RADIO-ISOTOPES.67.435.

Koyang F., Awe R., Bineng G. S., Ndimantchi A., Hamadou Y. A., Saïdou. Évaluation de l’exposition naturelle aux rayonnements due au 222Rn et aux sources de rayonnement externes : cas de l’Extrême-Nord, Cameroun. 2022. DOI:10.1097/HP.0000000000001609.

Shouop C. J. G., Moyo M. N., Chéné G., Mekontso E. J. N., Motapon O., Kayo S., Strivay D. Évaluation de la radioactivité naturelle et des risques radiologiques associés dans les matériaux de construction en sable utilisés dans la région du littoral de Douala au Cameroun, par spectrométrie gamma. 2017. DOI:10.1007/s12665-017-6474-3.

Ojo J., Joseph G. A. Doses de rayonnement terrestre provenant de certaines villes du sud-ouest du Nigéria. 2015. DOI:10.12691/IJP-3-6-4.

Ademola A. K., Bello A. K., Adejumobi A. C. Determination of natural radioactivity and hazard in soil samples in and around gold mining area in Itagunmodi, south-western, Nigeria. 2014. E-mail addresses: sirkay006@yahoo.com. http://dx.doi.org/10.1016/j.jrras.2014.06.001.

Turhan Ş., Arıkan İ. H., Oğuz F., Özdemir T., Yücel B., Varinlioğlu A., Köse A. Enquête embarquée sur le débit de dose gamma de fond naturel dans la région de Çanakkale, Turquie. 2012. DOI:10.1093/rpd/ncq593.

Sundal A.V. and Strand T. Indoor gamma radiation and radon concentrationsin a Norwegian carbonatite area. 2004. E-mail: aud.sundal@geo.uib.no. DOI : 10.1016/j.jenvrad.2004.03.007.

Kama E. and Bozkurt A. Environmental radioactivity measurements in Kastamonu region of northern Turkey. 2006. E-mail : kam@nukleer.gov.tr , bozkurt@harran.edu.tr. doi:10.1016/j.apradiso.2006.11.005.

Al-Saleh Ferdoas S. 2007. Measurements of indoor gamma radiation and radon concentrations in dwellings of Riyadh city, Saudi Arabia. Applied Radiation and Isotopes 65 (2007) 843–848. doi:10.1016/j.apradiso.2007.01.021. E-mail address: ferdoasalsaleh@hotmail.com.

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Publicado

02-10-2024

Edição

v. 12 n. 4 (2024)

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Artigos

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Direitos autorais (c) 2024 Brazilian Journal of Radiation Sciences

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Gamma radiation dose rate measurements in granite quarries and schools in two mountainous towns in Benin. Brazilian Journal of Radiation Sciences, Rio de Janeiro, Brazil, v. 12, n. 4, p. e2517, 2024. DOI: 10.15392/2319-0612.2024.2517. Disponível em: https://bjrs.org.br/revista/index.php/REVISTA/article/view/2517. Acesso em: 16 jul. 2025.