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Journal of Environmental Science and Health, Part A
Toxic/Hazardous Substances and Environmental Engineering
Volume 51, 2016 - Issue 7
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ARTICLES

Metals in agricultural produce associated with acid-mine drainage in Mount Morgan (Queensland, Australia)

Victoria A. Vicente-BeckettCentral Queensland University, School of Medical and Applied Sciences, Rockhampton, Queensland, AustraliaCorrespondence[email protected]
,
Gaylene J. Taylor McCauleyCentral Queensland University, School of Medical and Applied Sciences, Rockhampton, Queensland, Australia
&
Leo J. DuivenvoordenCentral Queensland University, School of Medical and Applied Sciences, Rockhampton, Queensland, Australia
Pages 561-570 | Received 28 Sep 2014, Published online: 16 Mar 2016

References

  • Harries, J. Acid Mine Drainage in Australia. Its Extent and Potential Future Liability; Supervising Scientist: Canberra, ACT, 1997.
  • Jones, D.R.; Chapman, B.M.; Riley, K.W.; Jung, R.F. Contamination of the Dee River at Low Flow by Past and Present Discharges from the Mt Morgan Mine; A Report to the Queensland Department of Minerals and Energy. CSIRO Minesite Rehabilitation Research Program; Glen Osmond, SA, 1995.
  • Jones, D.R. Impacts on the Dee River at Medium Flow by Discharges from the Mount Morgan Mine; CSIRO Minesite Rehabilitation Research Program. Glen Osmond, SA, 1996.
  • Taylor, G.; Howse, R.; Duivenvoorden, L.J.; Vicente-Beckett, V. Downstream flow event sampling of acid mine drainage from the historic Mt Morgan Mine. Water Sci. Technol. 2002, 45(11), 29–34.
  • Vicente-Beckett, V.; Taylor McCauley, G.J.; Duivenvoorden, L.J. Metal speciation in sediments and soils associated with acid-mine drainage in Mount Morgan (Queensland, Australia). J Environ Sci Health Part A, 2016, 51(2), 121–134.
  • Haworth, L. Pollution of the Dee River Resulting from Mining at Mount Morgan. Queensland Department of Local Government; Brisbane, QLD, 1975, 29 pp.
  • Garrido, A.E.; Condori, J.; Strosnider, W.H.; Nairn, R.W. Acid mine drainage impacts on irrigation water resources, agricultural soils, and potatoes in Potosi, Bolivia. 26th Annual Meeting of the American Society of Mining and Reclamation and 11th Billings Land Reclamation Symposium; Billings, MT, 2009, 480–493.
  • Garrido, A.E.; Strosnider, W.H.; Nairn, R.W. Accumulation of eco-toxic metals in potato plants under greenhouse conditions irrigated with synthetic acid mine drainage impacted water and health risk evaluation. Joint Mining Reclamation Conf. 2010 – 27th Meeting of the American Society of Mining and Reclamation, 12th Pennsylvania Abandoned Mine Reclamation Conf. and 4th Appalachian Regional Reforestation Initiative Mined Land Reforestation Conf. 2010, 337–364.
  • Strosnider, W.H.J.; Llanos Lopez, F.S.; Nairn, R.W. Acid mine drainage at Cerro Rico de Potosi II: severe degradation of the upper Rio Pilcomayo watershed. Environ. Earth Sci. 2011, 64, 911–923.
  • Kim, K.W.; Lee, H.K.; Yoo, B.C. The environmental impact of gold mines in the Yugu-Kwangcheon Au-Ag metallogenic province, Republic of Korea. Environ. Technol. 1998, 19(3), 291–298.
  • Jovanovic, N.Z.; Barnard, R.O.; Rethman, N.F.G.; Annandale, J.G. Crops can be irrigated with lime-treated acid mine drainage. Water SA 1998, 24(2), 113–122.
  • Annandale, J.G.; Jovanovic, N.Z.; Tanner, P.D.; Benade, P.D.; Du Plessis, H.M. The sustainability of irrigation with gypsiferous mine water and implications for the mining industry in South Africa. Mine Water Environ. 2002, 21(2), 81–90.
  • Lin, C.; Lu, W.; Wu, Y. Agricultural soils irrigated with acidic mine water: Acidity, heavy metals, and crop contamination. Aust. J. Soil Res. 2005, 43(7), 819–826.
  • Duivenvoorden, L.J. Aquatic macrophytes and heavy metal pollution in the Fitzroy River system, Central Queensland. The State of our Rivers Conference; Australian National University; Canberra, ACT, 1989, 7 pp.
  • Duivenvoorden, L.J. The Dee River: aquatic flora and acid mine discharge. In Water Weeds Management in Queensland: Workshop Proceedings; Yezdani, H., Ed.; Queensland University of Technology; Brisbane, QLD, 1992, 187–200.
  • Yeldham, J. Wowan Dululu Landcare Group, pers. comm. 1 August 2000.
  • Reuter, D.; Robinson, J. Plant Analysis. CSIRO Publishing; Collingwood, VIC, 1997.
  • Garnett, D. Becquerel Laboratories; Lucas Heights, NSW, pers. comm. 7 May 2001.
  • Handson, P.D.; Shelley, B.C. A review of plant analysis in Australia. Aust. J. Exp. Agr. 1993, 33(8), 1029–1038.
  • Peverill, K.I. Soil testing and plant analysis in Australia. Aust. J. Exp. Agr. 1993, 33(8), 963–971.
  • Bartha, S.; Kalincak, M.; Kladekova, D. Report on the intercomparison P-ALFALFA (No. 12–2-03) for the determination of essential and toxic elements in lucerne. Institute of Radioecology and Applied Nuclear Techniques; Kosice, 1989, 1–4.
  • Medved, J.; Stresko, V.; Kubova, J.; Polakovicova, J. Efficiency of decomposition procedures for the determination of some elements in soils by atomic spectroscopic methods. Fresenius J. Anal. Chem. 1998, 360, 219–224.
  • Moore, P.; Cobby, J. Introductory Statistics for Environmentalists. Prentice Hall Europe: Oxford 1998; 250 pp.
  • Fowler, J.; Cohen, L. Practical Statistics for Field Biology. Open University Press: Chichester, 1990; 224 pp.
  • Jones, D.R. Contaminant Source Study, Mount Morgan Mine. EWL Sciences; Darwin, NT, 2001.
  • Taylor, G.J. Chemical Impacts of Acid Mine Drainage in the Dee River, Downstream of the Mount Morgan Mine, Central Queensland, Australia; Master of Applied Science Thesis. Central Queensland University; Rockhampton, 2005.
  • Australian and New Zealand Environment and Conservation Council (ANZECC) and the Agriculture and Resource Management Council of Australia and New Zealand (ARMCANZ). Australian and New Zealand Guidelines for Fresh and Marine Water Quality, The National Water Quality Management Strategy. Volume 1: The Guidelines; Canberra, ACT, 2000.
  • Rauret, G.; Lopez-Sanchez, J. F.; Sahuquillo A.; Muntau, H.; Quevauviller, P. Indicative values for extractable contents (mass fractions) of Cd, Cr, Cu, Ni, Pb and Zn in sediment (CRM 601) following the modified BCR-sequential extraction (three-step) procedure. Addendum to EUR-report 17554 EN; European Commission; Geel, Belgium, 2000.
  • Sterritt, R.; Lester, J. The value of sewage sludge to agriculture and effects of the agricultural use of sludges contaminated with toxic elements: a review. Sci. Total Environ. 1980, 16, 55–90.
  • Geeson, N.A.; Abrahams, P.W.; Murphy, M.P.; Thornton, I. Fluorine and metal enrichment of soils and pasture herbage in the old mining areas of Derbyshire, UK. Agr., Ecosyst. Environ. 1998, 68(3), 217–231.
  • National Environment Protection Council (NEPC). National Environment Protection (Assessment of Site Contamination) Measure 1999; National Environment Protection Council; Canberra, ACT, 1999.
  • US National Research Council. Mineral Tolerance of Domestic Animals. National Academy of Sciences; Washington, DC, 1980.
  • Food Standards ANZ. The 23rd Australian Total Diet Study; Food Standards Australia New Zealand; Canberra, ACT, 2011.
  • US Food and Drug Administration. Total Diet Study Statistics on Element Results - 2006–2011; Centre for Food Safety and Applied Nutrition; College Park, Maryland, 2014.
  • Palarea-Albaladejo, J; Martín-Fernández, J.A. Values below detection limit in compositional chemical data. Anal. Chim. Acta. 2013, 746, 32–43.
  • Zhang, T.; Shan, X.; Li, F. L. Comparison of two sequential extraction procedures for speciation analysis of metals in soils and plant availability. Commun. Soil Sci. Plan. 1998 29, 1023–1034.
  • Kubova, J.; Matus, P.; Bujdos, M.; Hagarova, I.; Medved, J. Utilization of optimized BCR three-step sequential and dilute single extraction procedures for soil-plant metal transfer predictions in contaminated lands. Talanta 2008, 75, 1110–1122.
  • Moreno-Jimenez, E.; Garcia-Gomez, C.; Oropesa, A.L.; Esteban, E.; Haro, A.; Carpena-Ruiz, R.; Tarazona, J.V.; Peñalosa, J.M.; Fernandez, M.D. Screening risk assessment tools for assessing the environmental impact in an abandoned pyritic mine in Spain. Sci. Total Environ. 2011, 409, 692–703.
  • McKone, T.E; Maddalena, R.L. Plant uptake of organic pollutants from soil: bioconcentration estimates based on models and experiments. Environ. Toxicol. Chem. 2007, 26(12), 2494–2504.
  • Henning, B.J.; Snyman, H.G.; Aveling, T.A.S. Plant-soil interaction of sludge-borne heavy metals and the effect on maize (Zea mays L.) seedlings growth. Water SA 2001, 27, 71–78.
  • Adamo, P.; Iavazzo, P.; Albanese, S.; Agrelli, D.; De Vivo, B.; Lima, A. Bioavailability and soil-to-plant transfer factors as indicators of potentially toxic element contamination in agricultural soils. Sci. Total Environ. 2014, 500–501, 11–22.
  • Martinez-Sanchez, M.J.; Garcia-Lorenzo, M.L.; Perez-Sirvent, C.; Bech, J. Trace element accumulation in plants from an aridic area affected by mining activities. J. Geochem. Explor. 2012, 123, 8–12.
  • Shan, X-Q.; Chen, B; Zhang, T-H.; Li, F-L.; Wen, B.; Qian, J. Relationship between sulfur speciation in soils and plant availability. Sci. Total Environ. 1997, 199, 237–246.
  • Gigliotti, G.; Businelli, D.; Giusquiani, P. L. Trace metals uptake and distribution in corn plants grown on a 6-year urban waste compost amended soil. Agr. Ecosyst. Environ. 1996, 58, 199–206.
  • Prokop, Z.; Cupr, P.; Zlevorova-Zlamalikova, V.; Komarek, J.; Dusek, L.; Holoubek, I. Mobility, bioavailability, and toxic effects of cadmium in soil samples. Environ. Res. 2003, 91, 119–126.
  • Amat, S.; McKinnon, J.J.; Olkowski, A.A.; Penner, G.B.; Simko, E.; Shand, P.J.; Hendrick, S. Understanding the role of sulfur-thiamine interaction in the pathogenesis of sulfur-induced polioencephalomalacia in beef cattle. Res. Vet. Sci. 2013, 85, 1081–1087.
  • Lamb, D.T.; Ming, H.; Megharaj, M.; Naidu, R. Heavy metal (Cu, Zn, Cd and Pb) partitioning and bioaccessibility in uncontaminated and long-term contaminated soils. J. Hazard. Mater. 2009, 171, 1150–1158.
  • Intawongse, M.; Dean, J.R. In-vitro testing for assessing oral bioaccessibility of trace metals in soil and food samples. Trends in Anal. Chem. 2006, 25(9), 876–886.

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