Physico-chemical characteristics and heavy metal concentrations of copper mine wastes in Zambia: implications for pollution risk and restoration

Mutale N. Chileshe; Stephen Syampungani; Emma Sandell Festin; Mulualem Tigabu; Abolfazl Daneshvar; Per Christer Odén

doi:10.1007/s11676-019-00921-0

Journal of Forestry Research ›› 2019, Vol. 31 ›› Issue (4) : 1283 -1293. DOI: 10.1007/s11676-019-00921-0

Original Paper

Physico-chemical characteristics and heavy metal concentrations of copper mine wastes in Zambia: implications for pollution risk and restoration

Author information +

History +

PDF

Abstract

Soil characterization is a vital activity to develop appropriate and effective restoration protocols for mine wastelands while insights into the total content of heavy metals in the soil is an important step in estimating the hazards that the metals may pose to the vital roles of soil in the ecosystem. This study addressed the following research questions: (1) To what extent do the physico-chemical characteristics vary between mine waste sediments and the nearby forest soil? (2) Are the concentrations of heavy metals high enough to be considered as toxic? and (3) Are heavy metals present in mine waste sediments potential sources of pollution? We hypothesized that the physico-chemical characteristics of mine waste sediments are less favorably for plant establishment and growth while the concentrations of heavy metals are very high, thus restricting the success of revegetation of mine waste lands. Mine waste sediments were sampled following a diagonal transect across tailings dams, overburden dump sites and the local forest soil from the top layer (0–20 cm) using a closed auger. Samples were analyzed for arsenic, barium, lead, cadmium, cobalt, copper, chromium, nickel, vanadium, and zinc as well as for soil physico-chemical properties. The mine waste sediments were dominated by silt whilst the forest soil by sand particles, with significantly high bulk density in the former. Both the forest soil and overburden sediments were acidic than the alkaline tailings dam sediment. Total organic carbon and nitrogen contents were significantly low in mine wasteland substrates but the concentration of Ca and Mg were significantly higher in tailings dam substrate than the forest soil. The concentrations of available P, K and Na were similar across sites. The mean concentrations of heavy metals were significantly (p < 0.01) higher in mine waste sediments than the forest soil; except for cadmium (p = 0.213). The order of contamination by heavy metals on the tailings was Cu > Co > Ba > Ni > As > Zn > Pb > Cr > V > Cd, and that on the overburdens was Cu > Co > Ba > Ni > Zn > Cr > Pb > V > As > Cd. The pollution load index (PLI) was nearly twice higher for the tailings dam (8.97) than the overburden (5.84). The findings show that the copper mine wastes (the tailings dams and overburden waste rock sites) are highly contaminated by heavy metals; which, in turn, might pose serious hazards to human health and agricultural productivity. In addition, poor macro-nutrient availability, substrate compaction and soil acidity (particularly on overburden sites) coupled with toxic level of heavy metals would be the main challenges for successful phytostabilization of copper mine wastelands.

Keywords

Contamination factors / Overburden material / Phytostabilization / Pollution load index / Tailings dam

Cite this article

Download citation ▾

Mutale N. Chileshe, Stephen Syampungani, Emma Sandell Festin, Mulualem Tigabu, Abolfazl Daneshvar, Per Christer Odén. Physico-chemical characteristics and heavy metal concentrations of copper mine wastes in Zambia: implications for pollution risk and restoration. Journal of Forestry Research, 2019, 31(4): 1283-1293 DOI:10.1007/s11676-019-00921-0

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Addo MA, Darko EO, Gordon C, Nyarko BJB, Gbadago JK, Nyarko E, Affum HA, Botwe BO. Evaluation of heavy metals contamination of soil and vegetation in the vicinity of a cement factory in the Volta region, Ghana. Int J Sci Technol, 2012, 2(1): 40-50.

[2]	Adriano DC. Trace elements in terrestrial environments: biogeochemistry, bioavailability and risks of metals, 2001, New York: Springer.

[3]	Ahmad M, Lee SS, Lee SE, Al-Wabel MI, Tsang DCW, Ok YS. Biochar-induced changes in soil properties affected immobilization/mobilization of metals/metalloids in contaminated soils. J Soils Sediments, 2017, 17: 717-730.

[4]	Aubertin MG, Kardos TL. Root growth through porous media under controlled conditions. Soil sci Am Proc, 1965, 29: 290-293.

[5]	Bolan NS, Park JH, Robinson B, Naidu R, Huh KY. Phytostabilization: a green approach to contaminant containment. Adv Agron, 2011, 112: 145-204.

[6]	Brady NC, Weil RR. The nature and properties of soils, 1996, New Jersey: Prentice Hall Inc.

[7]	Bray RH, Kurtz LT. Determination of total, organic and available forms of phosphorus in soils. Soil Sci, 1945, 59: 39-45.

[8]	Bremner JM. Sparks. Nitrogen total. Methods of soil analysis Part 3 chemical methods, 1996, Madison: Soil Science Society of America Inc. & American Society of Agronomy Inc. 1085 1121

[9]	Bussinow M, Sarapatka B, Dlapa P. Chemical degradation of forest soil as a result of polymetallic ore mining activities. Polish J Environ Stud, 2012, 21(6): 1551-1561.

[10]	Chehregani A, Malayeri B, Golmohammadi R. Effects of heavy metals on the developmental stages of ovules and embryonic sacs in Euphorbia cheirandenia. Pak J Biol Sci, 2004, 8: 622-625.

[11]	Ciftci E, Kolayli H, Tokel S. Lead-Arsenic soil geochemical study as an exploration guide over the kill volcanogenic massive sulfide deposit, Northeastern Turkey. J Geochem Explor, 2005, 86(1): 49-59.

[12]	Das M, Maiti SK. Metal mine waste and phytoremediation. Asian J Water Environ Pollut, 2005, 4(1): 169-176.

[13]	Donahue RL, Miller RW, Shickluna JC. Soils: an introduction to soils and plant growth, 1990, New Delhi: Prentice-Hall.

[14]	Environmental Council of Zambia. State of the environment in Zambia, 2000, Lusaka: Environmental Council of Zambia.

[15]	Ettler V, Kříbek B, Majer V, Knésl I, Mihaljevič M. Differences in the bioaccessibility of metals/metalloids in soils from mining and smelting areas (Copperbelt, Zambia). J Geochem Explor, 2012, 113(1): 68-75.

[16]	Ezeaku PI, Davidson A. Analytical situations of land degradation and sustainable management strategies in Africa. J Agri Soc Sci, 2008, 4: 42-52.

[17]	Fernández-Cadena JC, Andrade S, Silva-Coello CL, De la Iglesia R. Heavy metal concentration in mangrove surface sediments from the north-west coast of South America. Marine Pollut Bull, 2014, 82: 221-226.

[18]	Gautam N, Gupta R, Mishra A, Singh R. Heavy metals and living systems: an overview. Indian J Pharmacol, 2011, 43(3): 246-253.

[19]	Ghaderian SM, Ravandi AAG. Accumulation of copper and other heavy metals by plants growing on Sarcheshmeh copper mining area, Iran. J Geochem Explor, 2013, 123: 25-32.

[20]	Government of the Republic of Zambia. Exploratory soils map of Zambia, 1991, Lusaka: Ministry of Agriculture, Survey Department.

[21]	Gowda SS, Reddy MR, Govila PK. Assessment of heavy metal contamination in soils at Jajmau (Kanpur) and Unnao Industrial areas of the Ganga Plain, Uttar Pradesh, India. J Hazard Mater, 2010, 174: 113-121.

[22]	Hakanson L. Ecological risk index for aquatic pollution control. A sedimentological approach. Water Res, 1980, 14(5): 975-1001.

[23]	Ikenaka Y, Nakayama SMM, Muzandu K, Choongo K, Teraoka H, Mizuno N, Ishizuka M. Heavy metal contamination of soil and sediment in Zambia. Afr J Environ Sci Technol, 2010, 4(11): 729-739.

[24]	James S, Brown J. Effects of biphenyl-A and other endocrine disruptors compared with abnormalities of schizophrenia: an endocrine disruption theory of schizophrenia. Schizophr Bull, 2009, 35(1): 256-278.

[25]	Kabata-Pendias A, Pendias H. Trace elements in soils and plants, 1992, Florida: CRC Press Inc.

[26]	Kapungwe ME. Heavy metal contaminated water, soils and crops in Peri urban wastewater irrigation farming in Mufulira and Kafue towns in Zambia. J Geogr Geol, 2013, 5(2): 55-72.

[27]	Khorasanipour AM, Majid H, Tangestani A, RezaNaseh B, Hajmohammadi H. Hydrochemistry, mineralogy and chemical fraction of mine and processing wastes, associated with porphyry copper mines: a case study from the Sarcheshmeh mine, Iran. Appl Geochem, 2011, 26: 714-730.

[28]	Kříbek B, Majer V, Veselovský F, Nyambe I. Discrimination of lithogenic and anthropogenic sources of metals and sulphur in soils of the central-northern part of the Zambian Copperbelt Mining District: a topsoil versus subsurface soil concept. J Geochem Explor, 2010, 104(3): 69-86.

[29]	Kuter N (2013) Reclamation of degraded landscapes due to opencast mining, advances in landscape architecture. http://www.intechopen.com/books/advances-in-landscape-architecture/reclamation-of-degraded-landscapes-due-to-opencast-mining. Accessed 14 Sept 2018.

[30]	Li MS, Luo YP, Su ZY. Heavy metal concentrations in soils and plant accumulation in a restored manganese mineland in Guangxi, South China. Environ Pollut, 2007, 147: 168-175.

[31]	Lima AT, Mitchell K, O’Connell DW, Verhoeven J, Van Cappellen P. The legacy of surface mining: remediation, restoration, reclamation and rehabilitation. Environ Sci Policy, 2016, 66: 227-233.

[32]	Liu WH, Zhao ZJ, Ouyang ZY, Solderland L, Liu HG. Impacts of sewage irrigation on heavy Metal distribution and contamination in Beijing, China. Environ Int, 2005, 31: 805-812.

[33]	Mashuta K, Lusapi J, Kamboyi V. Baseline soil mineralogy study of tailings dump 52 at Nkana mine site, 2010, Zambia: Ministry of Agriculture and Co-operatives.

[34]	Mendez MO, Maier RM. Phytostabilization of mine tailings in arid and semiarid environments-an emerging remediation technology. Environ Health Perspect, 2008, 116: 278-283.

[35]

M’kandawire E, Syakalima M, Muzandu K, Pandey G, Simuunza M, Nakayama SMMS, Kawai KY, Ikenaka Y, Ishizuka M. The nucleotide sequence of metallothioneins (MT) in liver of the Kafue lechwe (Kobus lechwe kafuensis) and their potential as biomarkers of heavy metal pollution of the Kafue River. Gene, 2012, 506(2): 310-316.

[36]	Monterroso C, Rodríguez F, Chaves R, Diez J, Becerra-Castro C, Kidd SP, Macías F. Heavy metal distribution in the mine soils and plants growing in a Pb/Zn mining area in NW Spain. Appl Geochem, 2014, 44: 3-11.

[37]	Nakayama MMS, Ikenaka Y, Hamada K, Muzandu K, Choongo K, Yabe J, Umemura T, Ishizuka M. Accumulation and biological effects of metals in wild rats in mining areas of Zambia. Environ Monit Assess, 2013, 185(6): 4907-4918.

[38]	Nelson DW, Sommers LE. Page AL. Total carbon, organic carbon, and organic matter. Methods of soil analysis, Part 2, chemical andmicrobiological properties, 1982, Madison: American Society of Agronomy, Inc. & Soil Science Society of America Inc. 539 579

[39]	Nikolaidis C, Zafiriadis I, Mathioudakis V, Constantinidis T. Heavy metal pollution associated with an abandoned lead–zinc mine in the Kirki region NE Greece. Bull Environ Contam Toxicol, 2010, 85(3): 307-312.

[40]	Nussbaumer Y, Cole MA, Offler CE, Patrick JW. Identifying and ameliorating nutrient limitations to reconstructing a forest ecosystem on mined land. Restor Ecol, 2016, 24: 202-211.

[41]	Nweke OM, UKpai NS. Use of enrichment, ecological risk and contamination factors with geoaccumulation indexes to evaluate heavy metal contents in the soils around Ameka mining area, South of Abakaliki, Nigeria. JGEESI, 2016, 5(4): 1-13.

[42]	O’Dell R, Silk W, Green P, Claassen V. Compost amendment of Cu-Zn minespoil reduces toxic bioavailable heavy metal concentrations and promotes establishment and biomass production of Bromus carinatus (Hook and Arn.). Environ Pollut, 2007, 148: 115-124.

[43]	Perlatti F, Ferreira TO, Romero RE, Costa MCG, Otero XL. Copper accumulation and changes in soil physical–chemical properties promoted by native plants in an abandoned mine site in northeastern Brazil: implications for restoration of mine sites. Ecol Eng, 2015, 82: 103-111.

[44]	Remon E, Bouchardonb J-L, Corniera B, Guyb B, Leclerca J-C, Faure O. Soil characteristics, heavy metal availability and vegetation recovery at a former metallurgical landfill: implications in risk assessment and site restoration. Environ Pollut, 2005, 137: 316-323.

[45]	Ross SM. Ross SM. Sources and forms of potentially toxic metals in soil-plant systems. Toxic metals in soil-plant systems, 1994, Chichester: Wiley 3 26

[46]	Sencindiver JC, Ammons JT. Barnhisel RI, Darmody RG, Daniels WL. Mine soils Genesis and Classification. Reclamation of drastically disturbed lands, 2000, Agronomy Series: Am Soc Agron 41

[47]	Seshan BRR, Natesan U, Deepthi K. Geochemical and Statistical approach for Evaluation of heavy metal pollution in core sediments in south east coast of India. Int J Environ Sci Technol, 2010, 7(2): 291-306.

[48]	Sheldrick BH, Wang C. Carter MR. Particle Size Distribution. Soil sampling and methods of analysis, Canadian Society of Soil Science, 1993, Ann Arbor: Lewis Publishers.

[49]	Sikaundi G (2013) Copper mining industry in Zambia: environmental challenges. http://unstats.un.org/unsd/environment. Accessed 6 Sept 2016

[50]	Sposito G. The chemistry of soils, 1989, New York: Oxford University Press.

[51]	Sracek O. Formation of secondary hematite and its role in attenuation of contaminants at mine tailings: review and comparison of sites in Zambia and Namibia. Front Environ Sci, 2015, 2: 64-75.

[52]	Syampungani S, Geldenhuys CJ, Chirwa P. Miombo woodland utilization and management, and impact perception among stakeholders in Zambia: a call for policy change in Southern Africa. J Nat Res Policy Res, 2011, 3(2): 163-181.

[53]	Thompson PJ, Jansen JI. Penetrometer resistance and bulk density as parameters for predicting root system performance in mine soils. Soil Sci Soc Am J, 1987, 51: 1288-1293.

[54]	Tomlinson DC, Wilson JG, Harris CR, Jeffery DW. Problems in the assessment of heavy metals levels in estuaries and the formation of a pollution index. Helgol Wiss Meeresunters, 1980, 33: 566-575.

[55]	Tutu H, McCarthy TS, Cukrowska E. The chemical characteristics of acid mine drainage with particular reference to sources, distribution and remediation: the Witwatersrand Basin, South Africa as a case study. Appl Geochem, 2008, 23: 3666-3684.

[56]	Venkateswarlu K, Nirola R, Kuppusamy S, Thavamani P, Naidu R, Megharaj M. Abandoned metalliferous mines: ecological impacts and potential approaches for reclamation. Rev Environ Sci Biotechnol, 2016, 15: 327-354.

[57]	Vogel H, Kasper B (2002) Mine soils on abandoned gold mine tailing in Francistown North-East District, Republic of Botswana. http://www.limpopo.riverawarenesskit.org/LIMPOPORAK_COM/_SYSTEM/DMSSTORAGE/3471EN/MINE_SOILS_FTOWN_SEC.PDF. Accessed 17 Feb 2017

[58]	Wild A. Soils and the Environment, 1993, Cambridge: Cambridge University Press.

[59]	Witheetrirong Y, Tripathi NK, Tipdecho T, Parkpian P. Estimation of the effect of soil texture on nitrate-nitrogen content in groundwater using optical remote sensing. Int J Environ Res Public Health, 2011, 8(8): 3416-3436.

[60]	Wong MH. Ecological restoration of mine degraded soils, with emphasis on metal contaminated soils. Chemosphere, 2003, 50: 775-780.

[61]	Wong JWC, Chen Q, Zhang FS, Wong MH, Baker AJM (1999) Phytostabilization of mimicked Cadmium contaminated soil with lime amendment. In: Wenzel WW (ed) Biogeochemistry of trace elements, international conference, Vienna, Austria

[62]	World Health Organization (2006) World reference base for heavy metals permissible limits for soil, World Health Organization

[63]	Yabe J, Nakayama MMS, Ikenaka Y, Muzandu K, Ishizuka M, Umemura T. Uptake of lead, cadmium and other metals in the liver and kidneys of cattle near a lead-zinc mine in Kabwe, Zambia. Environ Toxicol Chem, 2011, 30(8): 1892-1897.

[64]	Yabe J, Nakayama MMS, Ikenaka Y, Muzandu K, Ishizuka M, Umemura T. Accumulation of metals in the liver and kidneys of cattle from agricultural areas in Lusaka, Zambia. J Vet Med Sci, 2012, 74(10): 1345-1347.

[65]	Zhang MK, Ke ZX. Copper and Zinc enrichment in the different size fractions of organic matter from polluted soils. Pedosphere, 2004, 14(1): 27-36.

[66]	Zhuang P, McBride MB, Xia H. Health risks from heavy metals via consumption of food crops in the vicinity of Dabaoshan mine, South China. Sci Total Environ, 2009, 407(5): 1551-1561.