Instrumental neutron activation analysis, gamma spectrometry and geographic information system techniques in the determination and mapping of rare earth element in phosphogypsum stacks

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• 作者：Renata Coura Borges ; Déborah Inês Teixeira Fávaro…
• 关键词：Rare earth elements ; Instrumental neutron activation analysis ; Phosphogypsum ; Soil pollution
• 刊名：Environmental Earth Sciences
• 出版年：2016
• 出版时间：April 2016
• 年：2016
• 卷：75
• 期：8
• 全文大小：9,386 KB
• 参考文献：ABNT (1987) NBR 10006: Solubilização de resíduos. Associação Brasileira de Normas Técnicas, Rio de Janeiro
  Bellido AVB (1988) Neutron activation analysis of ancient Egyptian pottery. Ph. D. Thesis. University of Manchester, Manchester
  Bode P, Hoffman EL, Lindstrom RL, Parry SJ, Rosenberg RJ (1990). Practical Aspects of Operating a Neutron Activation Analysis Laboratory. In: Tecdoc 564. IAEA, Vienna, p 251
  Borges RC (2011) Caracterização Química e Radiológica do Fosfogesso de Imbituba-SC e Aspectos Ambientais do Uso na Recuperação de Solos Agrícolas. Ph. D. Thesis. Universidade Federal Fluminense, Niterói
  Bragança MJCS, Tauhata L, Clain AF, Moreira I (2003) Minerais fosfatados para serem utilizados como materiais de referência radioativos. In: Metrologia-2003.Sociedade Brasileira de Metrologia (SBM), Recife
  Chua H (1998) Bio-accumulation of environmental residues of rare earth elements in aquatic flora Eichhornia crassipes (Mart.) Solms in Guangdong Province of China. Sci Total Environ 214:79–85CrossRef
  Departamento Nacional de Produção Mineral (DNPM) (1993) Sumário Mineral 1992. Ministério das Minas e Energia, Brasília
  Einax JW, Soldt U (1999) Geostatistical and multivariate statistical methods for the assessment of polluted soils—merits and limitations. Chemometr Intell Lab 46:79–91CrossRef
  El-Taher A (2010) Rare earth elements content in geological samples from eastern desert, Egypt, determined by instrumental neutron activation analysis. Appl Radiat Isot 68:1859–1863CrossRef
  Embso P, McLaughlin PI, Breit GN, Bray EA, Koening AE (2015) Rare earth elements in sedimentary phosphate deposits: solution to the global REE crisis? Gondwana Res 27:776–785CrossRef
  Environmental Systems Research Institute—ESRI. 2011. Desktop Help 10.0—How IDW works. http://​help.​arcgis.​com/​en/​arcgisdesktop/​10.​0/​help/​index.​html#/​How_​IDW_​works/​009z000000750000​00/​ . (Accessed on 05 Nov 2012)
  Fernandes HM, Rio APM, Franklin MR (2004) Impactos Radiológicos da Indústria do Fosfato. CETEM, Rio de Janeiro
  Fortescue JAC (1992) Landscape geochemistry: retrospect and prospect - 1990. Appl Geochem 7:1–53CrossRef
  Gorbunov AV, Frontasyeva MV, Gundorina SF, Onischenko TL, Maksiuta BB, Pal CS (1992) Effect of agricultural use of phosphogypsum on trace elements in soils and vegetation. Sci Total Environ 122:337–346CrossRef
  Hu Z, Haneklaus S, Sparovek G, Schnug E (2006) Rare earth elements in soils. Commun Soil Sci Plan 37(9):1381–1420CrossRef
  Ihlen PM, Schiellerup H, Gautneb H, Skar O (2014) Characterization of apatite resources in Norway and their REE potential—a review. Ore Geol Rev 58:126–147CrossRef
  Kabata-Pendias A, Mukherjee AB (2007) Trace elements from soil to human. Springer, New YorkCrossRef
  Kabata-Pendias A, Pendias H (1992) Trace elements in soils and plants, 2nd edn. CRC Press, Boca Raton
  Koeberl O, Bayer PM (1992) Concentrations of rare earth elements in human brain tissue and kidney stones determined by neutron activation analysis. J Alloys Compd 180:63–70CrossRef
  Lapido-Loureiro FE (2008) Fertilizantes e sustentabilidade: o fósforo na agricultura brasileira. CETEM, Rio de Janeiro
  Le Bourlegat FM (2010) Disponibilidade de Metais em Amostras de Fosfogesso e Fertilizantes Fosfatados Utilizados na Agricultura. Instituto de Pesquisas Energéticas e Nucleares, São PauloCrossRef
  Lebedev VN, Lokshin EHP (1999) Method of isolation of rare-earth elements from phosphogypsum Patent Number(s): RU2158317-C1 Assignee: as Russia kola rare elements and minerals
  Lima RMF (1989) Novos coletores na flotação do minério fosfático de Tapira, Minas Gerais. Dissertação (Mestrado)—Universidade Federal de Minas Gerais, Minas Gerais
  Lokshin EHP, Vershkova YUA, Kalinnikov VT (2002) Recovering rare-earth minerals from phosphogypsum Patent Number(s): RU2225892-C1 Assignee: as Russia kola rare elements & minerals
  Lokshin EHP, Kalinnikov VT, Ivlev KG (2005) Method of recovering rare-earth elements from phosphogypsum Patent Number(s): RU2293781-C1 Assignee: as Russia kola rare elements & minerals
  Melamed R, Neto JF (2008) Fertilizantes: Agroindústria e Sustentabilidade. CETEM, Rio de Janeiro
  Mendonça, F, Danni-Oliveira IM (2007) Climatologia: noções básicas e climas do Brasil. São Paulo
  Menzel RG (1968) Uranium, radium and thorium content in phosphate rocks and their possible radiation hazard. J Agr Food Chem 16:231–235CrossRef
  Mitsui Fertilizer Company (2006) http://​www.​yoorin.​com.​br/​Folhetos/​Folheto_​Yoorin.​pdf . Accessed 15 Aug 2013
  Oliveira KAP (2012) Fator de Transferência de Elementos Terras Raras em Solos Tropicais Tratados com Fosfogesso. Universidade Federal de Minas Gerais, Belo Horizonte
  Picard S (2002) Rare earth element contents of jurassic fish and reptile teeth and their potential relation to seawater composition. Chem Geol 186:1–16CrossRef
  Rutherford PM, Dudas MJ, Samek RA (1994) Environmental impacts of phosphogypsum. Sci Total Environ 149:1–38CrossRef
  Sabbioni E, Pietra R, Gaglione P, Vocaturo G, Colombo F, Zanoni M, Rodi F (1982) Long-term occupational risk of rare earth pneumoconiosis. Sci Total Environ 25:310–316
  Sabiha-Javied, Waheed S, Siddique N, Tufail M, Chaudhry MM, Irfan N (2008) Elemental analysis of phosphate rocks: for sustainable agriculture in Pakistan. J Radionalytical Nucl Chem 278(1):17–24CrossRef
  Santos AJG, Mazzilli BP, Fávaro DIT, Silva PSC (2006) Partitioning of radionuclides and trace elements in phosphogypsum and its source materials based on sequential extraction methods. J Environ Radioact 87:52–61CrossRef
  Saueia CH, Mazzilli BP, Fávaro DIT (2005) Natural radioactivity in phosphate rock, phosphogypsum and phosphate fertilizers in Brazil. J Radioanal Nucl Chem 264(2):445–448CrossRef
  Sneller FEC, Kalf DF, Weltje L, Wezel Van AP (2000) Maximum permissible concentrations and negligible concentrations for rare earth elements (REEs). IVM National Institute for Public Health and the Environment, Report 601501011. Netherlands
  Souza DMG, Rein TA, Lobato E, Ritchey KD (1992) Sugestões para diagnose e recomendação de gesso em solos de cerrado. In: II Seminário sobre o uso de gesso na agricultura. Instituto Brasileiro do Fosfato, Uberaba
  Sun SS, McDonough WF (1989) Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes. Geol Soc Lon 42(2):313–345CrossRef
  Turra C, Fernandes EAN, Bacchi MA (2011) Evaluation on rare earth elements of Brazilian agricultural supplies. J Environ Chem Ecotox 3(4):86–92
  Tyler G (2004) Rare earth elements in soil and plant system—a review. Plant Soil 267:191–206CrossRef
  Uchida S, Tagami K, Hirai I (2007) Soil-to-plant transfer factors of stable elements and naturally occurring radionuclides (1) Upland field crops collected in Japan. J Nucl Sci Tech 44(4):628–640. doi:10.​1080/​18811248.​2007.​9711851 CrossRef
  Valkov AV, Valkov DA (1996) Procedure for extraction of rare earth elements from phosphogypsum includes dissolving phosphogypsum in water or mineral acid or inorganic salt solution Patent Number(s): RU2104938-C1 Assignee: MITSAR CO LTD
  Varella CAA, Junior DG de S (2008). Estudo do Interpolador IDW do Arcview para Utilização em Agricultura de Precisão [Study of IDW Interpolator of Arcview for Use in Precision Agriculture]. http://​www.​ufrrj.​br/​institutos/​it/​deng/​varella/​Downloads/​IT190_​principios_​em_​agricultura_​de_​precisao/​Aulas/​Estudo%20​do%20​interpolador%20​idw%20​arcview.​htm . (Accessed on 11 Nov 2012)
  
• 作者单位：Renata Coura Borges (1)
  Déborah Inês Teixeira Fávaro (3)
  Vanessa Godoy Caldas (1)
  Dejanira da Costa Lauria (2)
  Alfredo Victor Bellido Bernedo (4)
  
  1. Instituto de Engenharia Nuclear, Cidade Universitária-Ilha do Fundão, Rua Helio de Almeida 75, Rio De Janeiro-RJ, 21941-906, Brazil
  3. Instituto de Pesquisas Energéticas e Nucleares, Av. Lineu Prestes 2242, São Paulo-SP, 05508-000, Brazil
  2. Instituto de Radioproteção e Dosimetria, Av. Salvador Allende s/n, Jacarepaguá, Rio De Janeiro-RJ, 22780-160, Brazil
  4. Departamento de Geoquímica Ambiental, Instituto de Química, Universidade Federal Fluminense, Outeiro de São João Batista s/n, Campus do Valonguinho, Centro, Niterói-RJ, 24020-150, Brazil
  
• 刊物类别：Earth and Environmental Science
• 刊物主题：None Assigned
• 出版者：Springer Berlin Heidelberg
• ISSN：1866-6299

文摘

Phosphogypsum is a by-product from the phosphate fertilizer industry, disposed in huge stacks in open-air storage areas. Its use in agriculture may be a solution to decrease these stacks, because, among its other uses, phosphogypsum can be used as a soil amendment to provide calcium and sulphur for major crops. However, it contains rare earth elements (REE) from its raw material. The objective of this study was to determine the concentrations of REE in phosphogypsum stacks Imbituba (southern Brazil) in order to verify the possibility of contamination in the surrounding of the stacks due to the disposal and to ensure the safe use of phosphogypsum in agriculture. Samples of phosphogypsum were collected and REE were determined by neutron activation analysis and gamma spectrometry. There was no leaching of the REE through the profile of the stacks, which suggests that the occurrence of REE in the phosphogypsum is associated with the formation of sulphates, carbonates, fluorides and phosphates. The results indicate that application of phosphogypsum from Imbituba to agricultural soils can contribute to increase the concentration of rare earth elements in the cultivated soils, but these are not available to plant uptake.