Abstract
Dissolved major ions and important heavy metals including total arsenic and iron were measured in groundwater from shallow (25–33 m) and deep (191–318 m) tube-wells in southeastern Bangladesh. These analyses are intended to help describe geochemical processes active in the aquifers and the source and release mechanism of arsenic in sediments for the Meghna Floodplain aquifer. The elevated Cl− and higher proportions of Na+ relative to Ca2+, Mg2+, and K+ in groundwater suggest the influence by a source of Na+ and Cl−. Use of chemical fertilizers may cause higher concentrations of NH +4 and PO 3−4 in shallow well samples. In general, most ions are positively correlated with Cl−, with Na+ showing an especially strong correlation with Cl−, indicating that these ions are derived from the same source of saline waters. The relationship between Cl−/HCO −3 ratios and Cl− also shows mixing of fresh groundwater and seawater. Concentrations of dissolved HCO −3 reflect the degree of water–rock interaction in groundwater systems and integrated microbial degradation of organic matter. Mn and Fe-oxyhydroxides are prominent in the clayey subsurface sediment and well known to be strong adsorbents of heavy metals including arsenic. All five shallow well samples had high arsenic concentration that exceeded WHO recommended limit for drinking water. Very low concentrations of SO 2−4 and NO −3 and high concentrations of dissolved Fe and PO 3−4 and NH + 4 ions support the reducing condition of subsurface aquifer. Arsenic concentrations demonstrate negative co-relation with the concentrations of SO 2−4 and NO −3 but correlate weakly with Mo, Fe concentrations and positively with those of P, PO 3−4 and NH + 4 ions.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Acharyya SK (2002) Arsenic contamination in groundwater affecting major parts of southern West Bengal and parts of western Chhattisgarh: source and mobilization process. Curr Sci 82(6):740–744
Acharyya SK, Chakraborty P, Lahiri S, Raymahashay BC, Guha S, Bhowmik A (1999) Arsenic poisoning in the Ganges delta. Nature 401:545
Aggett J, O’Brien GA (1985) Detailed model for the mobility of arsenic in lacustrine sediments based on measurements in Lake Ohakuri. Environ Sci Technol 19:231–238
Ahmed KM, Bhattacharya P, Hassan MA, Akhter SH, Alam SMM, Bhuyian MAH, Imam MB, Khan AA, Sracek O (2004) Arsenic enrichment in groundwater of the alluvial aquifers in Bangladesh: an overview. Appl Geochem 19:181–200
Alloway BJ, Ayres DC (1997) Chemical principles of environmental pollution. Chapman and Hall, UK
Anawar HM, Akai J, Komaki K, Terao H, Yoshioka T, Ishizuka T, Safiullah S, Kato K (2003) Geochemical occurrence of arsenic in groundwater of Bangladesh: sources and mobilization processes. J Geochem Explor 77:109–131
Andreasen DC, Fleck WB (1997) Use of bromide: chloride ratios to differentiate potential sources of chloride in a shallow, unconfined aquifer affected by brackish-water intrusion. Hydrogeol J 5:17–26
Appelo CAJ, Postma D (1999) Geochemistry, groundwater and pollution. A A Balkema, Rotterdam, pp 535
Azcue JM, Nriagu JO (1994) Arsenic: Historical perspectives. In: Nriagu JO (eds) Arsenic in the environment Part I: Cycling and characterization: advances in environ. science and technology. Wiley, New York, pp 430
Basta NT, Ryan JA, Chaney RL (2005) Trace element chemistry in residual-treated soil: key concepts and metal bioavailability. J Environ Qual 34:49–63
Berner RA (1971) Principles of chemical sedimentology. McGraw–Hill, New York, pp 240
Bhattacharya P (2002) Arsenic contaminated groundwater from the sedimentary aquifers of South-East Asia. In: Bocanegra E, Martı´nez D, Massone H (eds) Groundwater and human development, Proceedings XXXII IAH and VI ALHSUD Congress, Mar udel Plata, Argentina, 21–25 October 2002, pp. 357–363
Bhattacharya P, Chatterjee D, Jacks G (1997) Occurrence of arsenic contaminated groundwater in alluvial aquifers from the delta plains, eastern India: options for safe drinking water supply. Water Resour Dev 13:79–92
Böhlke JK (2002) Groundwater recharge and agricultural contamination. Hydrogeol J 10:153–179. doi:10.1007/s10040-001-0183-3
Böhlke JK, Denver JM (1995) Combined use of groundwater dating, chemical, and isotopic analyses to resolve the history and fate of nitrate contamination in two agricultural watersheds, Atlantic coastal plain, Maryland. Water Resour Res 31:2319–2339
Brannon JM, Patrick WH (1987) Fixation, transformation and mobilization of arsenic in sediments. Environ Sci Technol 21:450–459
Breit GN, Foster AL, Perkins RB, Yount JC, King Trude, Welch AH, Whitney JW, Uddin N, Muneem AA, Alam M (2004) As-rich Ferric oxyhydroxide enrichments in the shallow subsurface of Bangladesh. In: Wanty RB, Seal RRII (eds) Proceedings of the eleventh international symposium on water-rock interaction WRI-11, Saratoga Springs, p. 1457–1461
Brinkman R (1977) Surface-water gley soils in Bangladesh: Genesis. Geoderma 17:111–144
Brye KR, Norman JM, Bundy LG, Gower S.T (2001) Nitrogen and carbon leaching in agroecosystems and their role in denitrification potential. J Environ Qual 30:58–70
BWDB-UNDP (1982) Groundwater survey: the hydrogeological conditions of Bangladesh. UNDP Technical Report DP/UN/BGD-74-009/1, 113p
BWDB (2005) Report of the deep aquifer characterization and mapping project, phase-I (Kachua), Bangladesh Water Development Board component
Chakraborti D (1995) Arsenic contamination in six districts of West Bengal, India: the background. In: Proceedings of international conference—arsenic in groundwater: cause, effect and remedy, Kolkata
Chapelle FH, Lovley DR (1992) Rates of bacterial metabolism in deep coastal-plain aquifers. Appl Environ Microbiol 56:1865–1874
Cornell RM, Schwertmann (1996) The iron oxides: Structure, properties, reactions, occurrences, and uses. VCH Verlagsgesellshaft, Weinheim
Davis JA, Kent DB (1990) Surface complexation modeling in aqueous geochemistry. Rev Miner 23:177–260
Davranche MI, Bollinger JC (2001) A desorption–dissolution model for metal release from polluted soil under reductive conditions. J Environ Qual 30:1581–1586
Dixon W, Chiwell B (1992) The use of hydrochemical sections to identify recharge areas and saline intrusions in alluvial aquifers, Southeast Queensland, Australia. J Hydrol 135:259–274
DPHE (1999) Groundwater studies for arsenic contamination in Bangladesh. Final report, rapid investigation phase. Department of Public Health Engineering, Government of Bangladesh. Mott MacDonald and British Geological Survey
DPHE (2000) Groundwater studies for arsenic contamination in Bangladesh. Supplemental data to final report, rapid investigation phase. Department of Public Health Engineering, Government of Bangladesh. British Geological Survey, available from http://www.bgs.ac.uk/arsenic
DPHE-BGS (2001) Arsenic contamination of groundwater in Bangladesh. British Geological Survey and Department of Public Health Engineering, Govt. of Bangladesh; rapid investigation phase, Final Report
DPHE-DANIDA (2001) Hydrgeology summary report. Department of Public Health Engineering–Danish International Development Assistance Water Supply and Sanitation Components, Ministry of Foreign Affairs, Government of Bangladesh. 129p
Dudal R (1957) Paddy soils. Presented at the first South East Asian soils conference, Manila, December 1957
Fetter CW (1994) Applied hydrogeology. Prentice Hall, New Jersey, 691p
Foster AL (2003) Spectroscopic investigations of arsenic species in solid phases. In: Welch AH, Stollenwerk KG (eds) Arsenic in groundwater: geochemistry and occurrence. Kluwer, pp 27–65
Freeze RA, Cherry JA (1979) Groundwater. Prentice-Hall, New Jersey, pp 604
Garrels RM (1967) Genesis of some ground waters from igneous rocks. In: Abelson PH (Eds) Researches in geochemistry. Wiley, New York, pp 405–421
Gime´nez E, Morell I (1997) Hydrogeochemical analysis of salinization processes in the coastal aquifer of Oropesa (Castellon, Spain). Environ Geol 29:118–131
Harvey CH, Swartz CH, Badruzzaman ABM, Keon-Blute N, Yu W, Ali MA, Jay J, Beckie R, Niedan V, Brabander D, Oates PM, Ashfaque KN, Islam S, Hemond HF, Ahmed MF (2002) Arsenic mobility and groundwater extraction in Bangladesh. Science 298:1602–1606
Harvey CH, Swartz C, Badruzzaman ABM, Keon-Blute N, Yu W, Ali MA, Jay J, Beckie R, Niedan V, Brabander D, Oates P, Ashfaque KN, Islam S, Hemond HF, Ahmed MF (2005) Groundwater arsenic contamination on the Ganges delta: biogeochemistry, hydrology, human perturbations, and human suffering on a large scale. C R Geosci 337:285–296
Kim M-J, Nriagu J, Haack S (2000) Carbonate ions and arsenic dissolution by groundwater. Environ Sci Technol 34:3094–3100
Komor SC, Anderson HW Jr (1993) Nitrogen isotopes as indicators of nitrate sources in Minnesota sand-plain aquifers. Ground Water 31(2):260–271
Krishnan M.S (1985) The geology of India and Burma, 6th edn. CBS, New Delhi
Lijklema L (1980) Interaction of orthophosphate with iron (III) and aluminum hydroxides. Environ Sci Technol 14:537–540
Lin Z, Puls RW (2000) Adsorption, desorption and oxidationof arsenic affected by clay minerals and aging process. Environ Pollut 39:753–759
Lovley DR (1990) Magnetite formation during nicrobial dissimilatory iron reduction. In: Frankel RB, Blakemore RP (eds) Iron biominerals. Plenum, New York, pp 151–166
Mahesha A, Nagaraja SH (1996) Effect of natural recharge on seawater intrusion in coastal aquifers. J Hydrol 174:211–220
Mallik S, Rajagopal N (1996) Groundwater development in the arsenic effected alluvial belt of West Bengal-some questions. Curr Sci 70:956–958
Manning BA, Goldberg S (1996) Modeling arsenate competitive adsorption on kaolinite, montmorillonite and illite, clays and clay minerals. Soil Sci Soc Am J 44:609–623, 60:121–131
Manning BA, Goldberg S (1997) Adsorption and stability of arsenic (III) at the clay mineral-water interface. Environ Sci Technol 31(7):2005–2011
McArthur JM, Ravenscroft P, Safiullah S, Thirlwall MF (2001) Arsenic in groundwater, testing pollution mechanisms for sedimentary aquifers in Bangladesh. Water Resour Res 37(1):109–117
Moormann FR, Breeman NV (1978) Soil forming processes in Aquatic rice lands. Rice: soil, water, land, Chapter 5. International Rice Research Institute, Philippines
Moore PA, Reddy KR (1994) Role of Eh and pH on phosphorus geochemistry in sediments of Lake Okeechobee, Florida. J Environ Qual 23:955–964
Moore JN, Ficklin WH, Johns C (1988) Partitioning of arsenic and metals in reducing sulfide sediments. Environ Sci Technol 22:432–437
Morell I, Gime´nez E, Esteller MV (1996) Application of principal components analysis to the study of salinization on the Castellon Plain (Spain). Sci Total Environ 177:161–171
Morgan JJ, Stumm W (1991) Chemical processes in the environment, relevance of chemical speciation. In: Merien E (Eds) Metals and their compounds in the environment. VCH Publishers, Germany, pp 67–103
Nickson R, McArthur J, Burgess W, Ahmed KM, Ravenscroft P, Rahman M (1998) Arsenic poisoning of Bangladesh groundwater. Nature 395:338
Nickson RT, McArthur JM, Ravenscroft P, Burgess WG, Ahmed KM (2000) Mechanism of arsenic release to groundwater, Bangladesh and West Bengal. Appl Geochem 15:403–413
Norra S, Berner ZA, Agarwala P, Wagner F, Chandrasekharam D, Stuben D (2005) Impact of irrigation with arsenic rich groundwater on soil and crops: a geochemical case study in West Bengal Delta Plain, India. Appl Geochem 20:1890–1906
Nriagu JO (1994) Arsenic in the environment: Part II: human health and ecosystem effects. Wiley, New York
Petersen AT, Hansen HCB, Nybroe O (2004) Time and moisture effects on total and bioavailable copper in soil water extracts. J Environ Qual 33:505–512
Quaghebeur M, Rate A, Rengel Z, Hinz C (2005) Desorption kinetics of arsenate from kaolinite as influenced by pH. J Environ Qual 34:479–486
Rai D, Eary LE, Zachara JM (1989) Environmental chemistry of chromium. Sci Total Environ 86:15–23
Ravenscroft P, McArthur JM, Hoque BA (2001) Geochemical and palaeohydrological controls on pollution of groundwater by arsenic. In: Chappell WR, Abernathy CO, Calderon RL (eds) Arsenic exposure and health effects, vol IV. Elsevier, Oxford, pp 53–77
Reddy KR, Patrick WH (1975) Effect of alternate aerobic and anaerobic conditions on redox potential, organic matter decomposition, and nitrogen loss in a flooded soil. Soil Biol Biochem 7:87–94
Robertson FN (1986) Occurrence and solubility controls of trace elements in groundwater in alluvial basins of Arizona. In: Anderson TW, Johnson AI (eds) Regional aquifer systems of United States, Southwest Alluvial Basins of Arizona. Am Water Res Assoc, Monog, Series 7:69–80
Robertson FN (1989) Arsenic in ground-water under oxidizing conditions, South-west United States. Environ Geochem Health 11:171–185
Safiullah S, Kabir A, Tareq SM, Khan MMK, Alam FR (1999) Removal of arsenic by composite porous materials based on Fe2O3−MnO2 laterite soil. J Bangladesh Chem Soc 12(2):185–192
Salama RB, Claus JO, Fitzpatrick RW (1999) Contributions of groundwater conditions to soil and water stalinization. Hydrogeol J 7:46–64
Scott MJ, Morgan JJ (1995) Reactions at oxide surfaces. 1. Oxidation of As (III) by systhetic bimessite. Environ Sci Technol 29(8):1898–1905
Smedley PL, Kinniburg DG (2001) A review of the source behavior and distribution of arsenic in natural waters. Appl Geochem 17:517–568
Soulsby C, Chen M, Ferrier RC (1998) Hydrogeochemistry of shallow groundwater in an upland Scottish catchment. Hydrol Process 12:1111–1127
Stollenwerk KG (2003) Geochemical processes controlling transport of arsenic in groundwater: a review of adsorption. In: Welch AH, Stollenwuerk KG (eds) Arsenic in groundwater: geochemistry and occurrence. Kuluwer, Dordrecht, pp 67–100
Sukhija BS, Varma VN, Nagabhushanam P, Reddy DV (1996) Differentiation of paleomarine and modern seawater intruded salinities in coastal groundwaters (of Karaikal and Tanjavur, India) based on inorganic chemistry, organic biomarker fingerprints and radiocarbon dating. J Hydrol 174:173–201
Sullivan KA, Aller RC (1996) Diagenetic cycling of arsenic in Amazon Shelf sediments. Geochim Cosmochim Acta 60:1465–1477
Tareq SM, Safiullah S, Anawar HM, Rahman MM, Ishizuka T (2003) Arsenic pollution in groundwater: a self-organizing complex geochemical process in the deltaic sedimentary environment, Bangladesh. Sci Total Environ 313:213–226
Tesorieroa AJ, Spruilla TB, Eimersb JL (2004) Geochemistry of shallow ground water in coastal plain environments in the southeastern United States: implications for aquifer susceptibility. Appl Geochem 19:1471–1482
Tokunaga TK, Wan J, Hazen TC, Schwartz E, Firestone MK, Sutton SR, Newville M, Olson KR, Lanzirotti A, Rao W (2003) Distribution of chromium contamination and microbial activity in soil aggregates. J Environ Qual 32:541–549
Uddin A, Lundberg N (1998) Cenozoic history of the Himalayan-Bengal system: sand composition in the Bengal Basin, Bangladesh. Geol Soc Am Bull 110:497–511
Van Beek CGEM, Hettinga FAM, Straatman R (1989) The effects of manure spreading and acid deposition upon groundwater quality in Vierlingsbeek, the Netherlands. Int Assoc Hydrol Sci Publ 185:155–162
Van Geen A, Zheng Y, Versteeg R, Stute M, Horneman A, Dhar R, Steckler M, Gelman A, Small C, Ahsan H, Graziano JH, Hussain I, Ahmed KM (2003) Spacial variability of arsenic in 6000 tubewells in a 25 km2 area of Bangladesh. Water Resour Res 39, art no 1140
Waycuhunas GA (1991) Crystal chemistry of Oxides and hydroxides: In: Lindsley DH (ed) Oxide minerals: petrologic and magnetic significance, Mineral Soc Am, p 11–68
Welch AH, Westjohn DB, Helsel DR, Wanty RB (2000) Arsenic in ground water of the United States: occurrence and geochemistry. Ground Water 38(4):589–604
WHO (2004) Guideline for drinking water quality, recommendations, vol 1, 3rd edn. World Health Organization, Geneva, p 515
Yan X-P, Kerrich R, Hendry MJ (2000) Distribution of arsenic (3), arsenic (5) and total inorganic arsenic in pore waters from a thick till and clay rich aquitard sequence, Saskatchewan, Canada. Geochim Cosmochim Acta 62:2637–2648
Yongje Kim, Lee KS, Koh DC, Lee DH, Lee SG, Park WB, Koh GW, Woo NC (2003) Hydrochemical and isotopic evidence of groundwater salinization in a coastal aquifer: a case study in Jeju volcanic island, Korea. J Hydrol 270:282–294
Young EO, Ross DS (2001) Phosphate release from seasonally flooded soils: alaboratory microcosm study. J Environ Qual 30:91–101
Zahid A, Hassan MQ (2007) Arsenic distribution and characterization of multi layer aquifer system in Bengal delta for sustainable use of groundwater. In: Pre-conference paper volume of International Conference on Water and Flood Management, vol 1, 12–14 March 2007, Dhaka, Bangladesh, pp 19–27
Zhang GL, Gong ZT (2003) Pedigenic evolution of paddy soils in different soil landscapes. Geoderma 115:15–29
Zhang G, Deng W, Yang YS, Salama RB (2007) Evolution study of a regional groundwater system using hydrochemistry and stable isotopes in Songnen Plain, northeast China. Hydrol Process 21:1055–1065
Zheng Y, Stute M, Van Geen A, Gavrieli I, Dhar R, Simpson HJ, Schlosser P, Ahmed KM (2004) Redox control of arsenic mobilization in Bangladesh groundwater. Appl Geochem 19:201–214
Acknowledgment
The authors would like to acknowledge Dr. Jorn Breuer, Institute of Agricultural Chemistry, University of Hohenheim, Dr. Sascha Kummer, Institute of Geosciences, University of Tuebingen for their kind support in performing laboratory analyses in Germany and Ratan K Majumder, Bangladesh Atomic Energy Commission and Kumamoto University, Japan and George N Breit, US Geological Survey Denver Federal Center, Colorado, USA for their support in exchanging views and ideas. The German Academic Exchange Service (DAAD) and Bangladesh Water Development Board are gratefully acknowledged for providing research fellowship to the first author to perform laboratory works in Germany and allowing to conduct the research, respectively.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Zahid, A., Hassan, M.Q., Balke, KD. et al. Groundwater chemistry and occurrence of arsenic in the Meghna floodplain aquifer, southeastern Bangladesh. Environ Geol 54, 1247–1260 (2008). https://doi.org/10.1007/s00254-007-0907-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00254-007-0907-3