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Subsurface Processes Controlling Reuse Potential of Treated Wastewater Under Climate Change Conditions

  • Pankaj Kumar Gupta
  • Brijesh Kumar Yadav
Chapter

Abstract

In the last few decades, investigation on ecohydrological interaction including biogeochemical characteristics has been an important research topic in hydrology due to its role in natural resource management. Despite the research focus on this subject, quantifying the geochemical processes controlling the moisture flow and solute transport remains awaited especially under climate change conditions. At the same time, the wastewater treated in conventional wastewater treatment systems are reported with the inefficient removal of many emerging contaminants particularly in rural areas and remote communities in low socioeconomic conditions. As a result, in many instances, the wastewater may get disposed without appropriate advance treatment that further contaminate the soil-water system. Thus, there are urgent needs of the research to assess the risk posed to groundwater and to develop improved knowledge frame of hydrologic and biogeochemical processes and of geologic features controlling contaminant migration in the subsurface. Therefore, the main focus of this chapter is to present the different biogeochemical processes controlling reuse potential of treated wastewater in the subsurface under climate change conditions. The different geochemical process involved during the fate and transport in the subsurface are clearly elaborated and exemplified. Further, the role of varying climatic conditions on biogeochemical makeup and transport is discussed thoroughly. A state of the art of the different aspects of modeling and practical approaches to quantify the governing biogeochemical processes in the subsurface is reviewed comprehensively. Finally, the methodological framework is charted on the basis of the technical and socioeconomic aspect to implement the potential reuse of wastewater and remedial measures in the field. The outcomes of this chapter are of direct use in applying remediation technique in the field and for the decision-making related to the planning of (waste) water under varying environmental conditions.

Keywords

Treated wastewater Contaminant transport Subsurface Environment Bioremediation Groundwater resources Climate change 

Notes

Acknowledgment

The University Grant Commission (UGC) Fellowship received by Mr. Pankaj K Gupta is duly acknowledged.

References

  1. Albrechtsen H-J, Christensen TH (1994) Evidence for microbial iron reduction in a landfill leachate-polluted aquifer Vejen, Denmark. Appl Environ Microbiol 60:3920–3925Google Scholar
  2. Alvarez PJJ, Illman WA (2006) Bioremediation and natural attenuation, process fundamentals and mathematical models. Wiley-Interscience. ISBN-10 0-471-65043-9Google Scholar
  3. Anitha K, Bolan NS, Müller K, Laurenson S, Naidu R, Kim WI (2012) The influence of wastewater irrigation on the transformation and bioavailability of heavy metal(loid)s in soil. Adv Agron 115:215–297CrossRefGoogle Scholar
  4. Arora HS, Cantor RR, Nemeth JC (1982) Land treatment: a viable and successful method of treating petroleum industry wastes. Environ Int 7:285–291CrossRefGoogle Scholar
  5. Arye G, Dror I, Berkowitz B (2010) Fate and transport of carbamazepine in soil aquifer treatment (SAT) infiltration basin soils. Chemosphere 82(2011):244–252Google Scholar
  6. Bales RC, Hinkle SR, Kroeger TW, Stocking K, Gerba CP (1991) Bacteriophage adsorption during transport through porous media: chemical perturbations and reversibility. Environ Sci Technol 25:2088–2095CrossRefGoogle Scholar
  7. Barcelona MJ, Holm TR (1991) Oxidation–reduction capacities of aquifer solids. Environ Sci Technol 25:1565–1572CrossRefGoogle Scholar
  8. Bernstein N, Bartal A, Friedman H, Rot I, Snir P, Chazan A, Ioffe M (2006) Application of treated wastewater for cultivation of roses (Rosa hybrida) in soil-less culture. Sci Hortic 108:185–193CrossRefGoogle Scholar
  9. Borden RC, Gomez CA, Becker MT (1995) Geochemical indicators of intrinsic bioremediation. Groundwater 33(2):180–189CrossRefGoogle Scholar
  10. Botros FE, Harter T, Onsoy YS, Tuli A, Hopmans JW (2009) Spatial variability of hydraulic properties and sediment characteristics in a deep alluvial unsaturated zone. Vadose Zone J 8(2):276–289CrossRefGoogle Scholar
  11. Burge WD, Enkiri MK (1978) Virus adsorption by five soil. J Environ Qual 7:73CrossRefGoogle Scholar
  12. Caliman FA, Gavirilescu M (2009) Pharmaceuticals, personal care products and endocrine disrupting agents in the environment – a review. Clean 37:277–303Google Scholar
  13. Central Ground Water Board, Ministry of Water Resources, Government of India (2008) Groundwater Scenario Ajmer District Rajasthan. District Groundwater Brochure, Western Region JaipurGoogle Scholar
  14. Chary NS, Kamala CT, Raj DSS (2008) Assessing risk of heavy metals from consuming food grown on sewage irrigated soils and food chain transfer. Ecotoxicol Environ Safe 69:513–524CrossRefGoogle Scholar
  15. Cheftez B, Mualem T, Ben-Ari J (2008) Sorption and mobility of pharmaceutical compounds in soil irrigated with reclaimed wastewater. Chemosphere 73:1335CrossRefGoogle Scholar
  16. Christensen TH et al (2000) Characterization of redox conditions in groundwater contaminant plumes. J Contam Hydrol 45(3–4):165–241CrossRefGoogle Scholar
  17. Chu Y, Jin Y, Baumann T, Yates MV (2003) Effect of soil properties on saturated and unsaturated virus transport through columns. J Environ Qual 32:2017–2025CrossRefGoogle Scholar
  18. Clement TP, Johnson CD, Sun Y, Klecka GM, Bartlett C (2000) Natural attenuation of chlorinated ethene compounds: model development and field-scale application at the Dover site. J Contam Hydrol 42(2–4):113–140CrossRefGoogle Scholar
  19. Clifton C et al. (2010) Water and climate change: impacts on groundwater resources and adaptation options. Water Working Notes, World Bank Group Water Sector Board Note No 25, 76 pGoogle Scholar
  20. CPCB (2009) Status of water supply, wastewater generation and treatment in Class I cities and Class II towns of India. Central Pollution Control BoardGoogle Scholar
  21. Destouni G, Darracq A (2009) Nutrient cycling and N2O emissions in a changing climate: the subsurface water system role. Environ Res Lett 4(3):035008CrossRefGoogle Scholar
  22. Dettinger MD, Cayan DR, Meyer MK, Jeton AE (2004) Simulated hydrologic responses to climate variations and change in the Merced, Carson, and American River Basins, Sierra Nevada, California, 1900–2099. Clim Chang 62:283–317CrossRefGoogle Scholar
  23. Dobson R, Schroth MH, Zeyer J (2007a) Effect of water-table fluctuation on dissolution and biodegradation of a multi-component, light nonaqueous-phase liquid. J Contam Hydrol 94:235–248CrossRefGoogle Scholar
  24. Dobson R, Schroth MH, Zeyer J (2007b) Effect of water-table fluctuation on dissolution and biodegradation of a multi-component, light nonaqueous-phase liquid. J Contam Hydrol 94:235–248CrossRefGoogle Scholar
  25. Earman S, Dettinger M (2011) Potential impacts of climate change on groundwater resources – a global review. J Water Climate Change 02(4):213–229 http://www.iwaponline.com/jwc/002/jwc0020213.htm CrossRefGoogle Scholar
  26. Ebele AJ, Abou-Elwafa Abdallah M, Harrad S (2017) Pharmaceuticals and personal care products (PPCPs) in the freshwater aquatic environment. Emerg Contam 3(2017):1–16Google Scholar
  27. EPA (2008) Nanotechnology for site remediation fact sheet. U.S. Environmental Protection Agency, (October), pp 1–17Google Scholar
  28. Farrah SR, Preston DR (1993) Adsorption of viruses to sand modified by in situ precipitation of metallic salts. Wiener Mitteilungen Wien 12:25–29Google Scholar
  29. Gardenas A, Simunek J, Jarvis NJ, van Genuchten MT (2006) Two-dimensional modelling of preferential water flow and pesticide transport from a tile-drained field. J Hydrol 329:647–660CrossRefGoogle Scholar
  30. Gharaibeh MA, Eltaif NI, Al-Abdullah B (2007) Impact of field application of treated wastewater on hydraulic properties of vertisols. Water Air Soil Pollut 184:347–353CrossRefGoogle Scholar
  31. Green TR et al (2011a) Beneath the surface of global change: impacts of climate change on groundwater. J Hydrol 405:532–560CrossRefGoogle Scholar
  32. Green TR et al (2011b) Beneath the surface of global change: impacts of climate change on groundwater. J Hydrol 405:532–560CrossRefGoogle Scholar
  33. Gunawardhana LN, Kazama S (2012) Statistical and numerical analysis of the influence of climate variability on aquifer water levels and groundwater temperatures: the impacts of climate change on aquifer thermal regimes. Global Planet Chang 86–87:66–78CrossRefGoogle Scholar
  34. Gupta PK, Shashi R, Yadav BK (2013) BTEX Biodegradation in soil-water system having different substrate concentrations. Int J Eng 2(12)Google Scholar
  35. Gupta PK, Yadav BK (2017) Chapter 8: Bioremediation of Non-Aqueous Phase Liquids (NAPLS) polluted soil and water resources. In: Environmental pollutants and their bioremediation approaches. CRC Press, Taylor and Francis Group, Boca Raton. ISBN 9781138628892Google Scholar
  36. Gupta PK, Joshi P (2017) Assessing groundwater resource vulnerability by coupling GIS based DRASTIC and solute transport model in Ajmer District, Rajasthan. Journal of Geological Society of India (Springer), DOI:  https://doi.org/10.1007/s12594-018-0958-y CrossRefGoogle Scholar
  37. Gupta PK, Sharma D (2018) Assessments of hydrological and hydro-chemical vulnerability of groundwater in semi-arid regions of Rajasthan, India. Sustainable Water Resources Management, 1-15.  https://doi.org/10.1007/s40899-018-0260-6.
  38. Gupta PK, Ranjan S, Kumar D (2018a) Groundwater pollution by emerging industrial pollutants and its remediation techniques. Chapter 2, In Recent advances in environmental management, CRC Press Taylor & Francis Group, ISBN 9780815383147, Vol 1Google Scholar
  39. Gupta PK, Abhishek YBK (2018b) Impact of hydrocarbon pollutants on partially saturated soil media in batch system: Morphological analysis using SEM techniques. Chapter 5, water quality management; Water Sci Technol, ISBN: 978-981-10-5794-6, Vol. 79, SpringerGoogle Scholar
  40. Harter T, Ginn TR, Onsoy YS, Horwath WR (2005) Spatial variability and transport of nitrate in a deep alluvial vadose zone. Vadose Zone J 4:41–54CrossRefGoogle Scholar
  41. IPCC (2007a) Climate change (2007). The physical science basis. In: Solomon S et al (eds) Contribution of working group I to the fourth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge/New York, p 996Google Scholar
  42. IPCC (2007b) Climate change (2007). Impacts, adaptation and vulnerability. In: Parry ML, Canziani OF, Palutikof JP, Linden PJVD, Hanson CE (eds) Contribution of working group II to the fourth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge/New YorkGoogle Scholar
  43. Jeribi M, Almir-Assad B, Langevin D, Henaut I, Argillier JF (2002) Adsorption kinetics of asphaltenes at liquid interfaces. J Colloid Interface Sci 256(2):268–272CrossRefGoogle Scholar
  44. Karn B, Kuiken T, Otto M (2009) Nanotechnology and in situ remediation: a review of the benefits and potential risks. Environ Health Perspect 117(12):1823–1831CrossRefGoogle Scholar
  45. Karvelas M, Katsoyiannis A, Samara C (2003) Occurrence and fate of heavy metals in the wastewater treatment process. Chemosphere 53(10):1201–1210CrossRefGoogle Scholar
  46. Kinney CA, Furlong ET, Kolpin DW, Burkhardt MR, Zaugg SD, Werner SL, Bossio JP, Benotti MJ (2008) Bioaccumulation of pharmaceuticals and other anthropogenic waste indicators in earthworms from agricultural soil amended with biosolid or swine manure. Environ Sci Technol 42:1863–1870CrossRefGoogle Scholar
  47. Klein RJT, Nicholls RJ (1999) Assessment of coastal vulnerability to climate change. Ambio 28(2):182–187Google Scholar
  48. Kushwah SK, Malik S, Singh A (2012) Water quality assessment of raw sewage and final treated water with special reference to waste water treatment plant Bhopal, MP, India. Res J Recent Sci 1(ISC-2011):185–190Google Scholar
  49. Levantesi C, La Mantia R, Masciopinto C, Böckelmann U, Ayuso-Gabella MN, Salgot M et al (2010) Quantification of pathogenic microorganisms and microbial indicators in three wastewater reclamation and managed aquifer recharge facilities in Europe. Sci Total Environ 408(21):4923–4930CrossRefGoogle Scholar
  50. Li YH, Wang S, Luan Z, Ding J, Xu C, Wu D (2003) Adsorption of cadmium(II) from aqueous solution by surface oxidized carbon nanotubes. Carbon 41(5):1057–1062CrossRefGoogle Scholar
  51. Lipson SM, Stotzky G (1984) Effect of proteins on Reovirus adsorption to clay minerals. Appl Environ Microbiol 8:525–530Google Scholar
  52. McCarthy KA, Johnson RL (1993) Transport of volatile organic compounds across the capillary fringe. Water Resour Res 29(6):1675–1683CrossRefGoogle Scholar
  53. Moore RS, Taylor DH, Sturman LS, Reddy MM (1981) Poliovirus adsorption by 34 minerals and soils. Appl Environ Microbiol 42:963–975Google Scholar
  54. Moore RS, Taylor DH, Reddy MM, Sturman LS (1982) Adsorption of reovirus by minerals and soils. Appl Environ Microbiol 44:852–859Google Scholar
  55. Mustapha HI, Rousseau D, van Bruggen J, Lens P (2011) Treatment performance of horizontal subsurface flow constructed wetlands treating inorganic pollutants in simulated refinery effluent. In: 2nd Biennial Engineering Conference. School of Engineering and Engineering Technology, Federal University of Technology, MinnaGoogle Scholar
  56. Mustapha HI, van Bruggen JJ, Lens PN (2015) Vertical subsurface flow constructed wetlands for polishing secondary Kaduna refinery wastewater in Nigeria. Ecol Eng 84:588–559.  https://doi.org/10.1016/j.ecoleng.2015.09.060 CrossRefGoogle Scholar
  57. Mustapha IH, Gupta PK, Yadav BK, van Bruggen JJA, Lens PNL (2018) Performance evaluation of duplex constructed wetlands for the treatment of diesel contaminated wastewater. In: Chemosphere.  https://doi.org/10.1016/j.chemosphere.2018.04.036 CrossRefGoogle Scholar
  58. Okuda T, Kobayashi Y, Nagao R, Yamashita N, Tanaka H, Tanaka S, Fujii S, Konishi C, Houwa I (2008) Removal efficiency of 66 pharmaceuticals during wastewater treatment process in Japan. Water Sci Technol 57(1):65–71CrossRefGoogle Scholar
  59. Petersen LW, Rolston DE, Moldrup P, Yamaguchi T (1994) Volatile organic vapor diffusion and adsorption in soils. J Environ Qual 23:799–805CrossRefGoogle Scholar
  60. Petersen LW, El-Farhan YH, Moldrup P, Rolston DE, Yamaguchi T (1996) Transient diffusion, adsorption, and emission of volatile organic vapors in soils with fluctuating low water contents. J Environ Qual 25:1054–1063CrossRefGoogle Scholar
  61. Pierson WL, Nittim R, Chadwick MJ, Bishop KA, Horton PR (2001) Assessment of changes to saltwater/freshwater habitat from reductions in flow to the Richmond river estuary, Australia. Water Sci Technol 43(9):89–97CrossRefGoogle Scholar
  62. Powers SE, Loureiro CO, Abriola LM, Weber WJ (1991) Theoretical study of the significance of non-equilibrium dissolution of nonaqueous-phase liquids in subsurface systems. Water Resour Res 27(4):463–477CrossRefGoogle Scholar
  63. Ranjan SP, Kazama S, Sawamoto M (2006) Effects of climate and land use changes on groundwater resources in coastal aquifers. J Environ Manag 80(1):25–35CrossRefGoogle Scholar
  64. Ranjan S, Gupta PK, Yadav BK (2018) Application of nano-materials in subsurface remediation techniques – challenges and future prospects. Chapter 6, In Recent advances in environmental management, CRC Press Taylor & Francis Group, ISBN 9780815383147, Vol 1Google Scholar
  65. Rose JB, Dickson LJ, Farrah SR, Carnahan RP (1996) Removal of pathogenic and indicator microorganisms by a full-scale water reclamation facility. Water Res 30:2785–2797CrossRefGoogle Scholar
  66. Saien J, Shahrezaei F (2012) Organic pollutants removal from petroleum refinery wastewater with nanotitania photocatalyst and UV Light Emission. Int J Photoenergy 2012:1–5CrossRefGoogle Scholar
  67. Savage N, Diallo MS (2005) Nanomaterials and water purification: opportunities and challenges. J Nanopart Res 7(4–5):331–342CrossRefGoogle Scholar
  68. Schijven JF, Hassanizadeh SM (2000) Removal of viruses by soil passage: overview of modeling, processes, and parameters. CRC Crit Rev Environ Sci Technol 30:49–127CrossRefGoogle Scholar
  69. Seeger EM, Kuschk P, Fazekas H, Grathwohl P, Kaestner M (2011) Bioremediation of benzene-, MTBE- and ammonia-contaminated groundwater with pilot-scale constructed wetlands. Environ Pollut 199:3769–3776CrossRefGoogle Scholar
  70. Senesi N, Plaza C (2007) Role of humification processes in recycling organic wastes of various nature and sources as soil amendments. Clean-Soil Air Water 35:26–41.  https://doi.org/10.1002/clen.200600018 CrossRefGoogle Scholar
  71. Sharma RK, Agrawal M, Marshall F (2007) Heavy metal contamination of soil and vegetables in suburban areas of Varanasi, India. Ecotoxicol Environ Saf 66(2):258–266CrossRefGoogle Scholar
  72. Sherif MM, Singh VP (1999) Effect of climate change on sea water intrusion in coastal aquifers. Hydrol Process 13(8):1277–1287CrossRefGoogle Scholar
  73. Simunek J, van Genuchten MT (2009) Modelling nonequilibrium flow and transport processes using HYDRUS. Vadose Zone J 7:782–797CrossRefGoogle Scholar
  74. Simunek J, Jarvis NJ, van Genuchten MT, Gardenas A (2003) Review and comparison of models for describing non-equilibrium and preferential flow and transport in the vadose zone. J Hydrol 272:14–35CrossRefGoogle Scholar
  75. Sinton LW, Finlay RK, Pang L, Scott DM (1997) Transport of bacteria and bacteriophages in irrigated effluent into and through an alluvial gravel aquifer. Water Air Soil Pollut 98:17–42Google Scholar
  76. Sobsey MD, Dean CH, Knuckles ME, Wagner RA (1980) Interactions and survival of enteric viruses in soil materials. Appl Environ Microbiol 40:92–101Google Scholar
  77. Soga K, Page JWE, Illangasekare TH (2004) A review of NAPL source zone remediation efficiency and the mass flux approach. J Hazard Mater 110(1–3):13–27CrossRefGoogle Scholar
  78. Sparks DL (2003) Environmental soil chemistry. Academic/China Translation & Printing Services Ltd., Amsterdam/Hong KongCrossRefGoogle Scholar
  79. Stuart M et al (2011) A review of the impact of climate change on future nitrate concentrations in groundwater of the UK. Sci Total Environ 409(15):2859–2873CrossRefGoogle Scholar
  80. Suthar S, Chhimpa V, Singh S (2009) Bacterial contamination in drinking water: a case study in rural areas of northern Rajasthan, India. Environ Monit Assess 159:43–50CrossRefGoogle Scholar
  81. Taylor RG et al (2013) Ground water and climate change. Nat Clim Chang 3:322–329CrossRefGoogle Scholar
  82. Ternes TA, Bonerz M, Herrmann N, Teiser B, Andersen HR (2007) Irrigation of treated wastewater in Braunscheug, Germany: an option to remove pharmaceuticals and musk fragrances. Chemosphere 66:894–904CrossRefGoogle Scholar
  83. Tobiszewski M, Tsakovski S, Simeonov V, Namieśnik J (2012) Chlorinated solvents in a petrochemical wastewater treatment plant: an assessment of their removal using self-organising maps. Chemosphere 87:87.  https://doi.org/10.1016/j.chemosphere.2012.01.057 CrossRefGoogle Scholar
  84. US EPA (2004) Guidelines for water reuse, EPA/625/R-04/108 SeptemberGoogle Scholar
  85. USEPA (U.S. Environmental Protection Agency) (1995) Light nonaqueous phase liquids. Office of solid waste and emergency response, Washington, DC. EPA/540/S-95/500Google Scholar
  86. Vilker VL, Meronek GC, Bulter PC (1983) Interaction of poliovirus with montmorillonite clay in phosphate-buffered saline. Eviron Sci Technol 17:631–634CrossRefGoogle Scholar
  87. Wang F (2008) Modeling the spatial distribution of nitrogen leaching from dairy farmland. Vadose Zone J 7(2):439–452CrossRefGoogle Scholar
  88. Watlington K (2005) Emerging nanotechnologies for site remediation and wastewater treatment. Environmental Protection Agency, Washington DCGoogle Scholar
  89. Wu S, Wallace S, Brix H, Kuschk P, Kirui WK, Masi FD (2015) Treatment of industrial effluents in constructed wetlands: Challenges, operational strategies and overall performance. Environ Pollut 201:107–120CrossRefGoogle Scholar
  90. Yadav BK, Hassanizadeh SM (2011) An overview of biodegradation of LNAPLs in coastal (semi)-arid environment. Water Air Soil Pollut 220:225.  https://doi.org/10.1007/s11270-011-0749-1 CrossRefGoogle Scholar
  91. Yadav BK, Junaid S (2014) Groundwater vulnerability assessment to contamination using soil moisture flow and solute transport modelling. J Irrig Drain Eng 141:04014077-1.  https://doi.org/10.1061/(ASCE)IR.1943-4774.0000841 CrossRefGoogle Scholar
  92. Yates MV, Yates SR, Wagner J, Gerba CP (1987) Modeling virus survival and transport in the subsurface. J Contam Hydrol 1:329–345CrossRefGoogle Scholar

Copyright information

© Springer Nature Singapore Pte Ltd. 2019

Authors and Affiliations

  • Pankaj Kumar Gupta
    • 1
  • Brijesh Kumar Yadav
    • 1
  1. 1.Department of HydrologyIndian Institute of Technology RoorkeeRoorkeeIndia

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