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Municipal solid waste landfill impact on sediments and surface water quality of Amsal River: A case study of Ziama Mansouriah landfill (Northeastern Algeria) | ||
| Caspian Journal of Environmental Sciences | ||
| دوره 19، شماره 1، فروردین 2021، صفحه 115-125 اصل مقاله (1010.5 K) | ||
| نوع مقاله: Research Paper | ||
| شناسه دیجیتال (DOI): 10.22124/cjes.2021.4502 | ||
| نویسندگان | ||
| Leila Benfridja1؛ Abderrezak Krika* 2؛ Fouad Krika3 | ||
| 1Department of Environmental Sciences and Agronomic Sciences, Faculty of Nature Life and Sciences, University of Mohamed Seddik BenYahia Jijel, BP 98 Ouled Aissa, Jijel 18000, Algeria | ||
| 2Laboratory of Biotechnology, Environment and Health, University Mohamed Seddik BenYahia Jijel , BP 98 Ouled Aissa, Jijel (18000) Algeria | ||
| 3LIME laboratory, Faculty of Sciences and Technology, University of Jijel BP 98 Ouled Aissa, Jijel 18000, Algeria | ||
| چکیده | ||
| Landfills represent possible sources of diverse contaminants that can cause human health and ecological problems. The purpose of this study is to assess the pollution caused by a leachate from Ziama Mensouriah municipal landfill (north-eastern Algeria) affecting sediments and surface water. The water quality has been evaluated using River Pollution Index (RPI). Sediment contamination assessment was carried out using the pollution indicators including: contamination factor (CF), pollution load index (PLI) and geo-accumulation index (Igeo). According to the results, the RPI of Amsal River indicates an unpolluted water at site 1 (S1) (RPI = 2.5), severely polluted water at landfill effluent discharge (S2) (RPI = 8.25) and moderately polluted once at site (S3) (RPI = 5.5). In sediments, the order of mean concentration (µg g-1) of metals was Pb (156.2) > Cd (1.76). Furthermore, spatial distribution of both metals in sediments showed a significantly higher concentration at S2 indicating that metal pollution is caused by leachate from the studied municipal landfill. The Igeo values reveal that Pb was significantly accumulated compared to Cd. The highest CF values (>6) of Pb and Cd determined at S2 promote a high Pb and Cd contamination in that specific station. The PLI results showed that all sites, except for S1, were moderately to extremely heavy contaminated. | ||
| کلیدواژهها | ||
| Landfill؛ Water؛ Sediments؛ Heavy metals؛ Algeria | ||
| مراجع | ||
|
Abu-Rukah, Y & Al-Kofahi, O 2001, The assessment of the effect of landfill leachate on ground-water quality - a case study, El-Akader Landfill Site - North Jordan. Journal of Arid Environments, 49: 615-630.
Ahdy, HHH & Khaled, A 2009, Heavy Metals Contamination in Sediments of theWestern Part of Egyptian Mediterranean Sea. Australian Journal of Basic and Applied Sciences, 3: 3330-3336.
Alam, P, Sharholy, M & Ahmad, K 2020, A Study on the Landfill Leachate and Its Impact on Groundwater Quality of Ghazipur Area, New Delhi, India. Recent Developments in Waste Management, 57:345-358.
APHA 2005, American Water Works Association. Standard methods for the examination of water and wastewater. New York, 264 p.
Azizi, A, Krika, A & Krika, F 2019, Heavy metal bioaccumulation and distribution in Typha latifolia and Arundo donax: implication for phytoremediation. Caspian Journal of Environmental Sciences, 18: 21-29.
Banu, Z, Chowdhury, MSA, Hossain, MD & Nakagami, K 2013, Contamination and ecological risk assessment of heavy metal in the sediment of Turag river, Bangladesh: An index analysis approach. Journal of Water Resource and Protection, 5: 239-248;
Bhouyan, AM 1979, Efect of industrial pollution on the biology of the Karnafully River. M. Phil. Thesis, University of Chittagong, Bangladesh. p 164.
Bhuiyan, MAH, Islam, MA, Dampare, SB, Parvez, L & Suzuki, S 2020, Evaluation of hazardous metal pollution in irrigation and drinking water systems in the vicinity of a coal mine area of north western Bangladesh. Journal of Hazardous Materials, 179: 1065-1077.
Chatanga, P, Ntuli, V, Mugomeri, E, Keketsi, T & Chikowore, NVT 2019, Situational analysis of physico-chemical, biochemical and microbiological quality of water along Mohokare River, Lesotho. Egyptian Journal of Aquatic Research, 45: 45-51.
De, S, Maiti, SK, Hazra, T, Debsarkar, A & Dutta, A 2016, Leachate characterization and identification of dominant pollutants using leachate pollution index for an uncontrolled landfill site. Global Journal of Environmental Science and Management, 2: 177-186.
Durmusoglu, E & Yilmaz, C 2006, Evaluation and temporal variation of raw and pre-treated leachate quality from an active solid waste landfill. Water Air and Soil Pollution, 171: 359-382.
Effendi, H 2003, Water quality analysis for aquatic resources management. Yogyakarta: Kanisius. 258 p.
Fang, JJ , Yang, N, Cen, DY, Shao, LM & He, PJ. 2012, Odor compounds from different sources of landfill: characterization and source identification. Waste Management, 32: 1401-1410.
Fernández, DS, Puchulu, ME & Georgieff, SM 2014, Identification and assessment of water pollution as a consequence of a leachate plume migration from a municipal landfill site (Tucumán, Argentina). Environmental Geochemistry and Health, 36: 489-503.
Grosbois, CA, Horowitz, AJ, Smith, JJ & Elrick, KA 2001, The effect of mining and related activities on the sediment-trace element geochemistry of Lake Coeur d’Alene, Idaho, USA. Part III. Downstream effects: the Spokane River Basin. Hydrological Processes, 15: 855-875.
Gupta, VK, Sadegh, H, Yari, M, Shahryari-Ghoshekandi, R, Maazinejad, B & Chahardori, M 2015, Removal of ammonium ions from wastewater. A short review in development of efficient methods. Global Journal of Environmental Science and Management, 1: 149-158.
Hakanson, L 1980 Ecological risk index for aquatic pollution control, a sedimentological approach. Water Research, 14: 975-1001.
Han, DM, Tong, XX, Currell, MJ, Cao, GL, Jin, MG & Tong, CS 2014, Evaluation of the impact of an uncontrolled landfill on surrounding groundwater quality, Zhoukou, China. Journal of Geochemical Exploration, 136: 24-39.
Hassan, M, Rahman, MATMT, Saha, B, Ibne Kamal, A.K 2015, Status of Heavy Metals in Water and Sediment of the Meghna River, Bangladesh. American Journal of Environmental Sciences, 11: 427-439.
Henniche, S 2014, Evaluation of the current Zn and Cd contents of soils and spontaneous vegetation of the Ziama Mensouria landfill. MSc. Dissertation, Department of Environmental Sciences and Agronomic Sciences, Faculty of Nature Life and Sciences, University of Mohamed Seddik BenYahia Jijel, Algeria, 34 p.
Islam, MS, Ahmed, MK, Raknuzzaman, M, Habibullah-Al-Mamun, M & Islam, MK 2015, Heavy metal pollution in surface water and sediment: A preliminary assessment of an urban river in a developing country. Ecological Indicators, 48: 282-291.
Kerolli-Mustafa, M, Fajković, H, Rončević, S & Ćurković, L 2015, Assessment of metals risks from different depths of jarosite tailing waste of Trepça Zinc Industry, Kosovo based on BCR procedure. Journal of Geochemical Exploration, 148:161-168.
Kjeldsen, P, Barlaz, MA, Rooker, P, Baun, A, Ledin, A, & Christensen, TH 2002, Present and long-term composition of MSW landfill leachate: A review. Critical Reviews in Environmental Science and Technology, 32: 297-336.
Krauskopf, KB & Bird, DK 1995, Introduction to Geochemistry, 3rd ed., WCB McGraw-Hill, Boston, MA.
Li, W, Hua, T, Zhou, Q, Zhang, S & Li, F 2010, Treatment of stabilized landfill leachate by the combined process of coagulation/flocculation and powder activated carbon adsorption. Desalination, 264: 56-62.
Liou, SM, Lo, SL & Hu, CY 2003, Application of two-stage fuzzy set theory to river quality evaluation in Taiwan. Water Research,37: 1406-1416.
Liou, SM, Lo, SL & Wang, SH 2004, A generalized water quality index for Taiwan. Environmental Monitoring and Assessment, 96: 35-52.
MacDonald, DD, Ingersoll, CG & Berger, TA 2000, Development and evaluation of consensus based sediment quality guidelines for freshwater ecosystems. Archives of Environmental Contamination and Toxicology, 39:20-31.
Mahmood, N, Chowdhury, MSU, Hossain, MM, Haider, SMB & Chowdhury, SR 1992, Review of the state of environment relating to marine fisheries of Bangladesh, Country status report, BOBP (FAO) MS.CU. p 85.
Melnyk, A, Kuklińska, KL, Wolska & Namieśnik, J 2014, Chemical pollution and toxicity of water samples from stream receiving leachate from controlled municipal solid waste (MSW) landfill. Environmental Research, 135:253-261.
Min, X, Xie, X, Chai, L, Liang, Y, Li, M & Ke, Y 2013, Environmental availability and ecological risk assessment of heavy metals in zinc leaching residue. The Transactions of Nonferrous Metals Society of China, 23:208-218.
Mishra, S, Singh, AL & Tiwary, D 2014, Studies of physico-chemical status of the ponds at Varanasi Holy City under Anthropogenic influences. Journal of Environmental Research and Development, 4:261-268.
Mohiuddin, KM., Ogawa, Y, Zakir, HM, Otomo, K & Shikazono, N 2011, Heavy metals contamination in water and sediments of an Urban river in a developing country. International Journal of Environmental Science and Technology, 8:723-736.
Mor, S, Ravindra, K, Dahiya, RP & Chandra, A 2006, Leachate characterization and assessment of groundwater pollution near municipal solid waste landfill site. Environmental Monitoring and Assessment, 118: 435-456.
Muller, G 1969, Index of geo-accumulation in the sediments of the Rhine River. GeoJournal, 2:108-118.
Müller, G 1981, Die Schwermetallbelstung der sedimente des Neckars und seiner Nebenflusse: eine Bestandsaufnahme. Chemical Zeitung, 105: 157-164 (In Germany).
Nartey,VK, Hayford, EK & Ametsi, SK 2012, Assessment of the Impact of Solid Waste Dumpsites on Some Surface Water Systems in the Accra Metropolitan Area, Ghana. Journal of Water Resource and Protection, 4: 605-615.
Prasanna, MB, Ranjan & PC 2010, Physico chemical properties of water collected from Dhamra estuary. International Journal of Environmental Science, 1: 329-334.
Robinson, HD 1995, A Review of the composition of leachates from domestic wastes in landfill sites. UK7 Aspinwall and Company for the Department of the Environment, 511 p.
Saison, C, Schwartz, C & Morel, JL 2004, Hyperaccumulation of metals by Thlaspi caerulescens as affected by root development and Cd-Zn/Ca-Mg interactions. International Journal of Phytoremediation, 6:49-61.
Schiopu, AM & Gavrilescu, M 2010, Options for the treatment and management of municipal landfill leachate: common and specific issues. CLEAN, 38: 1101-1110.
Segura-Muñoz, SI, Takayanagui, AMM, Trevilato, TMB & Santos, CB 2004, Trace element distribution in surface soil in the area of a municipal solid waste landfill and a medical waste incinerator. Bulletin of Environmental Contamination and Toxicology, 72:157-164;
Seshan, BRR, Natesan, U & Deepthi, K 2010, Geochemical and statistical approach for evaluation of heavy metal pollution in core sediments in southeast coast of India. International Journal of Environmental Science and Technology, 7: 291-306.
Szefer, P, Szefer, K, Glasby, GP, Pempkowiak, J & Kaliszan, R 1996, Heavy metal pollution in surficial sediments from the southern Baltic Sea off Poland. Journal of Environmental Science and Health, A31: 2723-2754.
Talabi, AT, Odunaike, KO, Akinyemi, LP & Bashiru BO 2020, Investigation for heavy metals in river waters in the federal capital territory, North Central of Nigeria. International Journal of Energy and Water Resources, 4: 213-219.
Talalaj, IA 2014, Assessment of groundwater quality near the landfill site using the modified water quality index. Environmental Monitoring and Assessment, 186:3673-3683.
Tomlinson, D, Wilson, J, Harris, C & Jeffrey, D 1980, Problems in the assessment of heavy metal levels in estuaries and the formation of a pollution index. Helgoländer Meeresun, 33: 566-575.
Tripathi, BD, Sikandar, M & Shukla, SC 1991, Physico-chemical characterization of city sewage discharged into river Ganga at Varanasi, India. Environment International, 17: 469-478.
Turekian, K & Wedepohl, KH 1961, Distribution of the elements in some major units of the earth’s crust. Geological Society of America Bulletin, 72: 175-192.
Vural, A, Gündogdu, A, Baltacı, C & Akpınar, I 2017, Environmental impact of Gümüshane City, Turkey, waste area in terms of heavy metal pollution. Natural Hazards, 88: 867-890. Doi: 10.1007/s11069-017-2896-1
Vural, A 2015, Contamination Assessment of Heavy Metals Associated with an Alteration Area: Demirören Gumushane, NE Turkey. Journal of Geological Society of India, 86: 215-222. Doi:10.1007/s12594-015-0301-9
WHO 2004, Environmental Chemistry, 2nd Edition, WH Freeman and Co., New York, p484 p. | ||
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