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Critical Reviews in Environmental Science and Technology Volume 47, 2017 - Issue 15
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Original Articles

The importance of key attenuation factors for microbial and chemical contaminants during managed aquifer recharge: A review

Julia RegneryDepartment of Civil and Environmental Engineering, Colorado School of Mines, Golden, CO, USACorrespondence[email protected]
,
Charles P. GerbaDepartment of Soil, Water and Environmental Science, University of Arizona, Tucson, AZ, USA
,
Eric R. V. DickensonDepartment of Civil and Environmental Engineering, Colorado School of Mines, Golden, CO, USA;Water Quality R&D, Southern Nevada Water Authority, Henderson, NV, USA
&
Jörg E. DrewesDepartment of Civil and Environmental Engineering, Colorado School of Mines, Golden, CO, USA;Chair of Urban Water Systems Engineering, Technical University of Munich, Garching, GermanyCorrespondence[email protected]
ORCID Iconhttp://orcid.org/0000-0003-2520-7596
ORCID Icon
Pages 1409-1452 | Published online: 08 Dec 2017

References

  • Abbaszedegan, M., LeChevallier, M., and Gerba, C. P. (2003). Occurrence of viruses in US groundwaters. Journal of the American Water Works Association, 95, 107–120.
  • Aharoni, A., Guttman, J., Cikurel, H., and Sharma, S. K. (2011). SWITCH – Sustainable water management in the city of the future: Guidelines for design and operation and maintenance of SAT (and hybrid SAT) system. Mekorot and UNESCO – IHE, D 3.2.1.f - i, (pp. 70).
  • Ahmed, W., Wan, C., Goonetileke, A., and Gardner, T. (2010). Evaluating sewage-associated JCV and BKV polyomaviruses for sourcing human fecal pollution in a coastal river in Southeast Queensland, Australia. Journal of Environmental Quality, 39, 1743–1750.
  • Alidina, M., Li, D., Ouf, M., and Drewes, J. E. (2014a). Role of primary substrate composition and concentration on attenuation of trace organic chemicals in managed aquifer recharge systems. Journal of Environmental Management, 144, 58–66.
  • Alidina, M., Li, D., and Drewes, J. E. (2014b). Investigating the role for adaptation of the microbial community to transform trace organic chemicals during managed aquifer recharge. Water Research, 56, 172–180.
  • Alidina, M., Shewchuk, J., and Drewes, J. E. (2015). Effect of temperature on removal of trace organic chemicals in managed aquifer recharge systems. Chemosphere, 122, 23–31.
  • Attinti, R., Wei, J., Kniel, K., Sims, J. T., and Jin, Y. (2010). Virus' (MS2, ϕX174, and Aichi) attachment on sand measured by atomic force microscopy and their transport through sand columns. Environmental Science and Technology, 44, 2426–2432.
  • Ayuso-Gabella, N., Page, D., Masciopinto, C., Aharoni, A., Salgot, M., and Wintgens, T. (2011). Quantifying the effect of Managed Aquifer Recharge on the microbiological human health risks of irrigating crops with recycled water. Agricultural Water Management, 99, 93–102.
  • Bae, J. and Schwab, K. J. (2008). Evaluation of murine norovirus, feline calicivirus, poliovirus, and MS2 as surrogates for human norovirus in a model of viral persistence in surface water and groundwater. Applied and Environmental Microbiology, 74, 477–484.
  • Balk, F. and Ford, F. A. (1999). Environmental risk assessment for the polycyclic musks AHTN and HHCB in the EU. I. Fate and exposure assessment. Toxicology Letters, 111, 57–79.
  • Bandara, V., Jayasumana, A. P., Pezeshki, A., Illangasekare, T. H., and Barnhart, K. (2010). Subsurface plume tracking using sparse wireless sensor networks. Electronic Journal of Structural Engineering, 10, 1–10.
  • Barbieri, M., Carrera, J. S., Ayora, C., Sanchez-Vila, X., Licha, T., Nödler, K., Osorio, V., Perez, S., Kock-Schulmeyer, M., Lopez de Alda, M. et al. (2012). Formation of diclofenac and sulfamethoxazole reversible transformation products in aquifer material under denitrifying conditions: Batch experiments. Science of the Total Environment, 426, 256–263.
  • Barnhart, K., Urteaga, I., Han, Q., Jayasumana, A., and Illangasekare, T. H. (2010). On integrating groundwater transport models with wireless sensor networks. Groundwater, 48, 771–780.
  • Bartak, R., Page, D., Sandhu, C., Grischek, T., Saini, B., Mehrotra, I., Jain, C. K., and Ghosh, N. C. (2015). Application of risk-based assessment and management to riverbank filtration sites in India. Journal of Water and Health, 13, 174–189.
  • Baumgarten, B., Jährig, J., Reemtsma, T., and Jekel, M. (2011). Long term laboratory column experiments to simulate bank filtration: factors controlling removal of sulfamethoxazole. Water Research, 45, 211–220.
  • Bertrand, I., Schijven, J. F., Sanchez, G., Wyn-Jones, P., Ottoson, J., Morin, T., Muscillo, M., Verani, M., Nasser, A., de Roda Husman, A.M. et al. (2012). The impact of temperature on the inactivation of enteric viruses in food and water: a review. Journal of Applied Microbiology, 112, 1059–1074.
  • Bertelkamp, C., Reungoat, J., Cornelissen, E. R., Singhal, N., Reynisson, J., Cabo, A. J., van der Hoek, J. P., and Verliefde, A. R. D. (2014). Sorption and biodegradation of organic micropollutants during river bank filtration: a laboratory column study. Water Research, 52, 231–241.
  • Bertelkamp, C., Verliefde, A. R. D., Schoutteten, K., Vanhaecke, L., Van den Bussche, J., Singhal, N., and van der Hoek, J. P. (2016). The effect of redox conditions and adaptation time on organic micropollutant removal during river bank filtration: A laboratory-scale column study. Science of the Total Environment, 544, 309–318.
  • Betancourt, W. Q., Kitajima, M., Wing, S. D., Regnery, J., Drewes, J. E., Pepper, I. L., and Gerba, C. P. (2014). Assessment of virus removal by managed aquifer recharge at three full-scale operations. Journal of Environmental Science and Health. Part A., 49, 1685–1692.
  • Betancourt, W. Q. (2016). Occurrence of viruses in groundwater beneath a managed aquifer recharge site in Arizona. Paper presented at the conference on ‘Aerobic spores and other microbial indicators to determine ground water under the influence of surface water’. Riverside, CA, September 6–8, 2016.
  • Beulke, S. and Brown, C. D. (2001). Evaluation of methods to derive pesticide degradation parameters for regulatory modeling. Biology and Fertility of Soils, 33, 558–564.
  • Blinkova, O., Rosario, K., Li, L., Kapoor, A., Slikas, B., Bernardin, F., Breitbart, M., and Delwart, E. (2009). Frequent detection of highly diverse variants of cardiovirus, cosavirus, bocavirus, and circovirus in sewage samples collected in the United States. Journal of Clinical Microbiology, 47, 3507–3513.
  • Borchardt, M.A., Spencer, S. K., Kieke, B. J., Lambertini, E., and Loge, F. J. (2012). Viruses in non-disinfected drinking water from municipal wells and community incidence of acute gastrointestinal illness. Environmental Health Perspectives, 120, 1272–1279.
  • Bradford, S. A., Leij, F. J., Schijven, J., and Torkzaban, S. (2017). Critical role of preferential flow in field-scale pathogen transport and retention. Vadose Zone Journal, 16, (4), 1–13.
  • Bradford, S. A., Schijven, J., and Harter, T. (2015). Microbial transport and fate in the subsurface environment: introduction to the special section. Journal of Environmental Quality, 44, 13333–13337.
  • Burke, V., Greskowiak, J., Asmuß, T., Bremermann, R., Taute, T., and Massmann, G. (2014a). Temperature dependent redox zonation and attenuation of wastewater-derived organic micropollutants in the hyporheic zone. Science of the Total Environment, 482–483, 53–61.
  • Burke, V., Richter, D., Hass, U., Duennbier, U., Greskowiak, J., and Massmann, G. (2014b). Redox-dependent removal of 27 organic trace pollutants: compilation of results from tank aeration experiments. Environmental Earth Science, 71, 3685–3695.
  • California Department of Public Health (CDPH) (2014). Groundwater Recharge Regulation. Sacramento, CA: Division of Drinking Water (formerly California Department of Public Health).
  • California Division of Drinking Water (2014). Groundwater Replenishment Using Recycled Water. Sacramento, CA: California State Water Resources Control Board, Division of Drinking Water.
  • Cartwright, C. D., Thompson, I. P., and Burns, R. G. (2000). Degradation and impact of phthalate plasticizers on soil microbial communities. Environmental Toxicology and Chemistry, 19, 1253–1261.
  • Chang, B. V., Liao, C. S., and Yuan, S. Y. (2005). Anaerobic degradation of diethyl phthalate, di-n-butyl phthalate, and di-(2-ethylhexyl) phthalate from river sediment in Taiwan. Chemosphere, 58, 1601–1607.
  • Charles, K. J., Souter, F. C., Baker, D. L., Davies, C. M., Schijven, J. F., Roser, D. J., Deere, D. A., Priscott, P. K., and Ashbolt, N. J. (2008). Fate and transport of viruses during sewage treatment in a mound system. Water Research, 42, 3047–3056.
  • Charles, K. J., Shore, J., Sellwood, J., Laverick, M., Hart, A., and Pedley, S. (2009). Assessment of the stability of human viruses and coliphage in groundwater by PCR and infectivity methods. Journal of Applied Microbiology, 106, 1827–1837.
  • Chenini, F. (2011). Overview of new practices in the reclaimed water reuses in the Mediterranean countries. Wastewater treatment and reuse in the Mediterranean region. In D. Barceló and M. Petrovic (Eds.), The Handbook of Environmental Chemistry. (pp. 43–62). Berlin / Heidelberg: Springer.
  • Chu, Y., Jin, Y, Flurry, M., and Yates, M. V. (2001). Mechanisms of virus removal during transport in unsaturated media. Water Resources Research, 37, 253–263.
  • de Roda Husman, A. M. R., Lodder, W. J., Rutjes, S. A., Schijven, J. F., and Teunis, P. F. M. (2009). Long-term inactivation study of three enteroviruses in artificial surface and ground waters using PCR and cell culture. Applied and Environmental Microbiology, 75, 1050–1057.
  • Díaz-Cruz, M. S. and Barceló, D. (2008). Trace organic chemicals contamination in ground water recharge. Chemosphere, 72, 333–342.
  • Dillon, P. (2005). Future management of aquifer recharge. Hydrogeology Journal, 13, 313–316.
  • Dillon, P., Toze, S., Page, D., Vanderzalm, J., Bekele, E., Sidhu, J., and Rinck-Pfeiffer, S. M. (2010). Managed aquifer recharge: rediscovering nature as a leading edge technology. Water Science and Technology, 62, 2338–2345.
  • Dowd, S. E., Pillai, S. D., Wang, S., and Corapcioglu, M. Y. (1998). Delineating the specific influence of virus isoelectric point and size on virus adsorption and transport through sandy soil. Applied and Environmental Microbiology, 64, 405–410.
  • Drewes, J. E., Hoppe, C., and Jennings, T. (2006). Fate and transport of N-nitrosamines under conditions simulating full-scale groundwater recharge operations. Water Environment Research, 78, 2466–2473.
  • Drewes, J. E., Sedlak, D. L., Snyder, S., and Dickenson, E. R. V. (2008). Development of indicators and surrogates for chemical contaminant removal during wastewater treatment and reclamation. Alexandria, VA: WateReuse Research Foundation.
  • Drewes, J. E. (2009). Ground water replenishment with recycled water – water quality improvements during managed aquifer recharge. Ground Water, 47, 502–505.
  • Drewes, J. E. and Khan, S. J. (2011). Water reuse for drinking water augmentation. In J. K. Edzwald (Ed.). Water quality and treatment, (6th edition. 16. pp. 1–16). Denver: American Water Works Association. 48.
  • Drewes, J. E., Dickenson, E. R. V., and Snyder, S. (2011). Development of surrogates to determine the efficiacy of groundwater recharge systems for the removal of trace organic chemicals. Alexandria, VA: WateReuse Research Foundation.
  • Drewes, J. E., Gerba, C. P., Snyder, S. A., Missimer, T., Regnery, J., and Dickenson, E. (2015). Role of retention time in the environmental buffer of indirect potable reuse projects – An investigation on managed aquifer recharge. Report WRRF-10-05, WateReuse Research Foundation, Alexandria, VA.
  • Drewes, J. E. and Letzel, T. (eds.) (2016). Assessing Transformation Products of Chemicals by Non-Target and Suspect Screening – Strategies and Workflows. Volume 2. Washington, DC: ACS Symposium Series American Chemical Society.
  • Drumheller, Z., Smits, K. M., Illangasekare, T. H., Regnery, J., Lee, J., and Kitanidis, P. K. (2017). Optimal decision making algorithm for managed aquifer recharge and recovery operation using near real‐time data: Benchtop scale laboratory demonstration. Groundwater Monitoring and Remediation, 37, 27–41.
  • Durán-Álvarez, J. C., Prado, B., González, D., Sánchez, Y., and Jiménez-Cisneros, B. (2015). Environmental fate of naproxen, carbamazepine and triclosan in wastewater, surface water and wastewater irrigated soil — Results of laboratory scale experiments. Science of the Total Environment, 538, 350–362.
  • EC (2013). Directive 2013/39/EU of the European Parliament and of the Council of 12 August 2013 amending Directives 2000/60/EC and 2008/105/EC as regards priority substances in the field of water policy. Official Journal of the European Union, Retrieved from http://eur-lex.europa.eu/legal-content/En/TXT/?qid=1448032144816&uri=CELEX:32013L0039.
  • Elkayam, R., Michail, M., Mienis, O., Kraitzer, T., Tal, N., and Leh, O. (2015). Soil aquifer as disinfection unit. Journal of Environmental Engineering, 141, 05015001.
  • Environment Protection and Heritage Council (2008). Australian Guidelines for Water Recycling: Managing Health and Environmental Risks (Phase 2): Augmentation of Drinking Water Supplies. Australia: Environment Protection and Heritage Council Canberra.
  • Environment Protection and Heritage Council (2009). Australian Guidelines for Water Recycling: Managing Health and Environmental Risks (Phase 2): Managed Aquifer Recharge. Australia: Environment Protection and Heritage Council Canberra.
  • Fawell, J., Le Corre, K., and Jeffrey, P. (2016). Common or independent? The debate over regulations and standards for water reuse in Europe. International Journal of Water Resources Development, 32, 559–572.
  • Ferrey, M. L., Wilson, J. T., Adair, C., Su, C., Fine, D. D., Liu, X., and Washington, J. W. (2012). Behavior and fate of PFOA and PFOS in sandy aquifer sediment. Groundwater Monitoring and Remediation, 32, 63–71.
  • Florida Department of Environmental Protection (2006). Reuse of Reclaimed Water and Land Application, (pp. 62–610). Tallahassee, FL: Florida Administrative Code.
  • Gerba, C. P. (1984). Applied and theoretical aspects of virus adsorption to surfaces. Advances in Applied Microbiology, 30, 133–168.
  • Gerba, C. P. and Goyal, S. M. (1985). Pathogen removal from wastewater during groundwater recharge. In T., Asano (Ed.), Artificial recharge of groundwater. (pp. 283–317). Boston: Butterworth Publishers.
  • Gerba, C. P., Yates, M. Y., and Yates, S. R. (1991). Quantitation of factors controlling viral and microbial transport in the subsurface. In Hurst, C. (ed.), Modeling the environmental fate of microorganisms. (pp. 77–88). Washington: American Society for Microbiology.
  • Gerba, C. P., Betancourt, W. Q., and Kitajima, M. (2017). How much reduction of virus is needed for recycled water: a continuous changing need for assessment? Water Research, 108, 25–31
  • Greskowiak, J., Prommer, H., Massmann, G., and Nützmann, G. (2006). Modeling seasonal redox dynamics and the corresponding fate of the pharmaceutical residue phenazone during artificial recharge of groundwater. Environmental Science and Technology, 40, 6615–6621.
  • Gross-Wittke, A., Gunkel, G., and Hoffmann, A. (2010). Temperature effects on bank filtration: redox conditions and physical-chemical parameters of pore water at Lake Tegel, Berlin, Germany. Journal of Water and Climate Change, 1, 55–66.
  • Grünheid, S., Amy, G., and Jekel, M. (2005). Removal of bulk dissolved organic carbon (DOC) and trace organic compounds by bank filtration and artificial recharge. Water Research, 39, 3219–3228.
  • Grünheid, S., Hübner, U., and Jekel, M. (2008). Impact of temperature on biodegradation of bulk and trace organics during soil passage in an indirect reuse system. Anglais, 57, 587–597.
  • Grützmacher, G. and Reuleaux, M. (2011). Literature study on redox control for infiltration oonds and other subsurface systems. Wasser, Berlin, Germany: KompetenzZentrum.
  • Haas, C. N., Rose, J. B., and Gerba, C. P. (2014). Quantitative microbial risk assessment. (2nd edition). NY: John Wiley and Sons.
  • Haramoto, E., Katayama, H., Oguma, K., and Ohgaki, S. (2007). Recovery of naked viral genomes in water in Japan. Water Research, 142, 169–173.
  • He, K., Echigo, S., and Itoh, S. (2016). Effect of operating conditions in soil aquifer treatment on the removals of pharmaceuticals and personal care products. Science of the Total Environment, 565, 672–681.
  • Heberer, T., Mechlinski, A., Fanck, B., Knappe, A., Massmann, G., Pekdeger, A., and Fritz, B. (2004). Field studies on the fate and transport of pharmaceutical residues in bank filtration. Groundwater Monitoring and Remediation, 24, 70–77.
  • Heberer, T., Massmann, G., Fanck, B., Taute, T., and Dünnbier, U. (2008). Behaviour and redox sensitivity of antimicrobial residues during bank filtration. Chemosphere, 73, 451–460.
  • Hellauer, K., Mergel, D., Ruhl, A. S., Filter, J., Hübner, U., Jekel, M., and Drewes, J. E. (2017). Advancing sequential managed aquifer recharge technology (SMART) using different intermediate oxidation processes. Water, 9, 221–234.
  • Henzler, A. F., Greskowiak, J., and Massmann, G. (2014). Modeling the fate of organic micropollutants during river bank filtration (Berlin, Germany). Journal of Contaminant Hydrology, 156, 78–92.
  • Henzler, A. F., Greskowiak, J., and Massmann, G. (2016). Seasonality of temperatures and redox zonations during bank filtration – A modeling approach. Journal of Hydrology, 535, 282–292.
  • Hoppe-Jones, C., Oldham, G., and Drewes, J. E. (2010). Attenuation of total organic carbon and unregulated trace organic chemicals in U.S. riverbank filtration systems. Water Research, 44, 4643–4659.
  • Hübner, U., Miehe, U., and Jekel, M. (2012). Optimized removal of dissolved organic carbon and trace organic contaminants during combined ozonation and artificial groundwater recharge. Water Research, 46, 6059–6068.
  • Hurst, C. J., Gerba, C. P., and Cech, I. (1980a). Effects of environmental variables and soil characteristics on virus survival in soil. Applied and Environmental Microbiology, 40, 1067–1079.
  • Hurst, C. J., Gerba, C. P., Lance, J. C., and Rice, R. R. (1980b). Survival of enteroviruses in rapid-infiltration basins during the land application of wastewater. Applied and Environmental Microbiology, 40, 192–200.
  • Husman, A. M. R., Lodder, W. J., Rutjes, S. A., Schijven, J. F., and Teunis, P. F. M. (2009). Long-term Inactivation study of three enteroviruses in artificial surface and groundwaters using PCR and Cell Culture. Applied and Environmental Microbiology, 75, 1050–1057.
  • Ikner, L. A., Gerba, C. P., and Bright, K. R. (2012). Concentration and recovery of viruses from water: a comprehensive review. Food and Environmental Virology, 4, 41–67.
  • John, J. E. and Rose, J. B. (2005). Review of factors affecting microbial survival in groundwater. Environmental Science and Technology, 39, 7345–7356.
  • Johnson, C. J., Phillips, K. S., McKenzie, P. T. D., Aiken, J. M., and Pedersen, J. A. (2006). Prions adhere to soil minerals and remain infectious. PLos Pathogen, 2, 296–302.
  • Katayama, H., Haramoto, E., Oguma, K., Yamashita, H., Tajima, A., Nakajima, H., and Ohgaki, S. (2008). One-year monthly quantitative survey of noroviruses, enteroviruses, and adenoviruses in wastewater collected from six plants in Japan. Water Research, 42, 1441–1448.
  • Kazner, C., Wintgens, T., Dillon, P. (eds.) (2012). Water reclamation technologies for safe managed aquifer recharge. London, UK: IWA Publishing.
  • Klecka, G. M., Gonsior, S. J., West, R. J., Goodwin, P. A., and Markham, D. A. (2001). Biodegradation of bisphenol A in aquatic environments: river die-away. Environmental Toxicology and Chemistry, 20, 2725–2735.
  • Kloppmann, W., Aharoni, A., Chikurel, H., Dillon, P., Gaus, I., Guttman, J., Kraitzer, T., Kremer, S., Masciopinto, C., Miotlinski, K., and Pavelic, P. (2012). Use of groundwater models for prediction and optimisation of the behaviour of MAR sites. In C. Kazner, T. Wintgens, and P. Dillon (Eds.), Water reclamation technologies for safe managed aquifer recharge. (pp. 311). London, UK: IWA Publishing.
  • Knappett, P. S. K., Emelko, M. B., Zhuang, J., and McKay, L. D. (2008). Transport and retention of a bacteriophage and microspheres in saturated, angular porous media: Effects of ionic strength and grain size. Water Research, 42, 4368–4378.
  • Koba, O., Golovko, O., Kodesova, R., Fer, M., and Grabic, R. (2016). Antibiotics degradation in soil: A case of clindamycin, trimethoprim, sulfamethoxazole and their transformation products. Environmental Pollution. 220, 1251–1263.
  • Kodesová, R., Grabic, R., Kocárek, M., Klement, A., Golovko, O., Fér, M., Nikodem, A., and Jaksík, O. (2015). Pharmaceuticals' sorptions relative to properties of thirteen different soils. Science of the Total Environment, 511, 435–443.
  • Kodesová, R., Kocárek, M., Klement, A., Golovko, O., Koba, O., Fér, M., Nikodem, A., Vondrácková, L., Jaksík, O., and Grabic, R. (2016). An analysis of the dissipation of pharmaceuticals under thirteen different soil conditions. Science of the Total Environment, 544, 369–381.
  • Kunkel, U. and Radke, M. (2008). Biodegradation of acidic pharmaceuticals in bed sediments: Insight from a laboratory experiment. Environmental Science and Technology, 42, 7273–7279.
  • Kuster, M., Díaz-Cruz, S., Rosell, M., López de Alda, M., and Barceló, D. (2010). Fate of selected pesticides, estrogens, progestogens and volatile organic compounds during artificial aquifer recharge using surface waters. Chemosphere, 79, 880–886.
  • Lance, C. P. and Lance, J. C. (1978). Poliovirus removal from primary and secondary sewage effluent by soil filtration. Applied and Environmental Microbiology, 36, 247–251.
  • Lange, F. T., Scheurer, M., and Brauch, H. J. (2012). Artificial sweeteners – A recently recognized class of emerging environmental contaminants: a review. Analytical and Bioanalytical Chemistry, 403, 2503–2518.
  • Lapworth, D. J., Baran, N., Stuart, M. E., and Ward, R. S. (2012). Emerging organic contaminants in groundwater: A review of sources, fate and occurrence. Environmental Pollution, 163, 287–303.
  • Laws, B. V., Dickenson, E. R. V., Johnson, T. A., Snyder, S. A., and Drewes, J. E. (2011). Attenuation of contaminants of emerging concern during surface-spreading aquifer recharge. Science of the Total Environment, 409, 1087–1094.
  • Lekkerkerker-Teunissen, K., Chekol, E. T., Maeng, S. K., Ghebremichael, K., Houtman, C. J., Verliefde, A. R. D., Verberk, J. Q. J. C., Amy, G. L., and van Dijk, J. C. (2012). Pharmaceutical removal during managed aquifer recharge with pretreatment by advanced oxidation. Water Science and Technology: Water Supply, 12, 755–767.
  • Li, D., Sharp, J. O., Saikaly, P., Ali, S., Alidina, M., Alarawi, M. S., Keller, S., Hoppe-Jones, C., and Drewes, J. E. (2012). Dissolved organic carbon influences microbial community composition and diversity in geographically distinct managed aquifer recharge systems. Applied and Environmental Microbiology, 78, 6819–6828.
  • Li, D., Alidina, M., Ouf, M., Sharp, J. O., Saikaly, P., and Drewes, J. E. (2013a). Microbial community evolution during simulated managed aquifer recharge in response to different biodegradable dissolved organic carbon (BDOC) concentrations. Water Research, 47, 2421–2430.
  • Li, D., Alidina, M., and Drewes, J. E. (2014). Role of primary substrate composition on microbial community structure and function and trace organic chemical attenuation in managed aquifer recharge systems. Applied Microbiology and Biotechnology, 98, 4347–4353.
  • Li, J., Jiang, L., Liu, X., and Lv, J. (2013b). Adsorption and aerobic biodegradation of four selected endocrine disrupting chemicals in soil-water system. International Biodeterioration and Biodegradation, 76, 3–7.
  • Liew, P. F. and Gerba, C. P. (1980). Thermostabilization of enteroviruses by estuarine sediment. Applied and Environmental Microbiology, 40, 305–308.
  • Lim, T. H., Gin, K. Y. H., Chow, S. S., Chen, Y. H., Reinhard, M., and Tay, J. H. (2007). Potential for 17 β-estradiol and estrone degradation in a recharge aquifer system. Journal of Environmental Engineering, 133, 819–826.
  • Lim, K. Y., Hamilton, A. J., and Jiang, S. C. (2015). Assessment of public health risk associated with viral contamination in harvested urban stormwater for domestic applications. Science of the Total Environment, 523, 95–108.
  • Limsawat, S. and Ohgaki, S. (1997). Fate of liberated viral RNA in wastewater determined by PCR. Applied and Environmental Microbiology, 63, 2932–2933.
  • Liu, Y. S., Ying, G. G., Shareef, A., and Kookana, R. S. (2011). Biodegradation of the ultraviolet filter benzophenone-3 under different redox conditions. Environmental Toxicology and Chemistry, 31, 289–295.
  • Liu, P. C., Mailloux, B. J., Wagner, A., Magyar, J. S., and Culligan, P. J. (2016). Can varying velocity conditions be one possible explanation for difference between laboratory and field observations of bacterial transport in porous media? Advances in Water Resources, 88, 97–108.
  • Maeng, S. K., Ameda, E., Sharma, S. K., Grützmacher, G., and Amy, G. L. (2010). Organic micropollutant removal from wastewater effluent-impacted drinking water sources during bank filtration and artificial recharge. Water Research, 44, 4003–4014.
  • Maeng, S. K., Sharma, S. K., Lekkerkerker-Teunissen, K., and Amy, G. L. (2011). Occurrence and fate of bulk organic matter and pharmaceutically active compounds in managed aquifer recharge: a review. Water Research, 45, 3015–3033.
  • Maliva, R. G. and Missimer, T. M. (2010). Aquifer storage and recovery and managed aquifer recharge using wells: planning, hydrogeology, design, and operation. Sugar Land, TX: Schlumberger.
  • Maliva, R. G. (2014). Economics of managed aquifer recharge. Water, 6, 1257–1279.
  • Mansell, J. and Drewes, J. E. (2004). Fate of steroidal hormones during soil-aquifer treatment (SAT). Groundwater Monitoring and Remediation, 24, 94–101.
  • Mashtare, M. L., Lee, L. S., Nies, L. F., and Turco, R. F. (2013). Transformation of 17α-estradiol, 17β-estradiol, and estrone in sediments under nitrate- and sulfate-reducing conditions. Environmental Science and Technology, 47, 7178–7185.
  • Massmann, G., Greskowiak, J., Dünnbier, U., Zühlke, S., Knappe, A., and Pekdeger, A. (2006). The impact of variable temperatures on the redox conditions and the behaviour of pharmaceutical residues during artificial recharge. Journal of Hydrology, 328, 141–156.
  • Massmann, G., Sültenfuß, J., Dünnbier, U., Knappe, A., Taute, T., and Pekdeger, A. (2008). Investigation of groundwater residence times during bank filtration in Berlin: a multi-tracer approach. Hydrological Processes, 22, 788–801.
  • Matthess, G., Pekdeger, A., and Schroeter, J. (1988). Persistence and transport of bacteria and viruses in groundwater – A conceptual evaluation. Journal of Contaminant Hydrology, 2, 171–188.
  • Michen, B. and Graule, T. (2010). Isoelectric points of viruses. Journal of Applied Microbiology, 109, 388–397.
  • Mitch, W., Sharp, J., Trussell, R., Valentine, R., Alvarez-Cohen, L., and Sedlak, D. (2003). N-nitrosodimethylamine (NDMA) as a drinking water contaminant: a review. Environmental Engineering Science, 20, 389–404.
  • Monteiro, S. C. and Boxall, A. B. A. (2010). Occurrence and fate of human pharmaceuticals in the environment. Reviews of Environmental Contamination and Toxicology, 202, 53–154.
  • Naess, H., Nyland, M., Husken, T., Follestad, I., and Nyland, H. I. (2012). Chronic fatigue syndrome after Giardia enteritis: clinical characteristics, disability and long-term sickness absence. BMC Gastroenterology, 8, 12–13.
  • Nham, H. T. T., Greskowiak, J., Nödler, K., Rahman, M.A., Spachos, T., Rusteberg, B., Massmann, G., Sauter, M., and Licha, T. (2015). Modeling the transport behavior of 16 emerging organic contaminants during soil aquifer treatment. Science of the Total Environment, 514, 450–458.
  • Ogorzaly, L., Bertrand, I., Paris, M., Maul, A., and Gantzer, C. (2010). Occurrence, survival, persistence of human adenoviruses and F-specific RNA phages in raw groundwater. Applied and Environmental Microbiology, 76, 8019–8025.
  • Onesios, K. M. and Bouwer, E. J. (2012). Biological removal of pharmaceuticals and personal care products during laboratory soil aquifer treatment simulation with different primary substrate concentrations. Water Research, 46, 2365–2375.
  • Onesios-Barry, K. M., Berry, D., Proescher, J. B., Sivakumar, I. K. A., and Bouwer, E. J. (2014). Removal of pharmaceuticals and personal care products during water recycling: microbial community structure and effects of substrate concentration. Applied and Environmental Microbiology, 80, 2440–2450.
  • Pachepsky, Y. A. and Shelton, D. R. (2011). Escherichia coli and fecal coliforms in freshwater and estuarine sediments. Critical Reviews in Environmental Science and Technology, 41, 1067–1110.
  • Page, D., Dillon, P., Vanderzalm, J., Toze, S., Sidhu, J., Barry, K., Levett, K., Kremer, S., and Regel, R. (2010). Risk assessment of aquifer storage transfer and recovery with urban stormwater for producing water of a potable quality. Journal of Environmental Quality, 39, 2029–2039.
  • Page, D., Gonzalez, D., Torkzaban, S., Toze, S., Sidhu, J., Miotliński, K., Barry, K., and Dillon, P. (2015). Microbiological risks of recycling urban stormwater via aquifers for various uses in Adelaide, Australia. Environmental Earth Sciences, 73, 7733–7737.
  • Page, D., Vanderzalm, J., Dillon, P., Gonzalez, D., and Barry, K. (2016). Stormwater quality review to evaluate treatment for drinking water supply via managed aquifer recharge. Water, Air, & Soil Pollution, 227, 322.
  • Pal, A., He, Y., Jekel, M., Reinhard, M., and Yew-Hoong Gin, K. (2014). Emerging contaminants of public health significance as water quality indicator compounds in the urban water cycle. Environment International, 71, 46–62.
  • Pang, L. (2009). Microbial removal rates in subsurface media estimated from published studies of field experiments and large intact soil cores. Journal of Environmental Quality, 38, 1531–1559.
  • Patterson, B. M., Shackleton, M., Furness, A. J., Pearce, J., Descourvieres, C., Linge, K. L., Busetti, F., and Spadek, T. (2010). Fate of nine recycled water trace organic contaminants and metal(loid)s during managed aquifer recharge into a anaerobic aquifer: Column studies. Water Research, 44, 1471–1481.
  • Patterson, B. M. and Bekele, E. B. (2011). A novel technique for estimating wetting front migration rates through the vadose zone based on changes in groundwater velocity. Journal of Hydrology, 409, 538–544.
  • Patterson, B. M., Shackleton, M., Furness, A. J., Bekele, E., Pearce, J., Linge, K. L., Busetti, F., Spadek, T., and Toze, S. (2011). Behaviour and fate of nine recycled water trace organics during managed aquifer recharge in an aerobic aquifer. Journal of Contaminant Hydrology, 122, 53–62.
  • Patterson, B. M., Pitoi, M. M., Furness, A. J., Bastow, T. P., and McKinley, A. J. (2012). Fate of N-nitrosodimethylamine in recycled water after recharge into anaerobic aquifer. Water Research, 46, 1260–1272.
  • Postigo, C. and Barceló, D. (2015). Synthetic organic compounds and their transformation products in groundwater: Occurrence, fate and mitigation. Science of the Total Environment, 503–504, 32–47.
  • Qadir, M., Boelee, E., Amerasinghe, P., and Danso, G. (2015). Costs and benefits of using wastewater for aquifer recharge. In P. Drechsel, M. Qadir, and D. Wichelns (eds.), Wastewater: economic asset in an urbanizing world. (pp. 153–167). Netherlands: Springer.
  • Rauch, T. and Drewes, J. E. (2005). Quantifying biological organic carbon removal in groundwater recharge systems. Journal of Environmental Engineering, 131, 909–923.
  • Rauch-Williams, T., Hoppe-Jones, C., and Drewes, J. E. (2010). The role of organic matter in the removal of emerging trace organic chemicals during managed aquifer recharge. Water Research, 44, 449–460.
  • Ray, C., Grischek, T., Hubbs, S., Drewes, J. E., Haas, D. C. D., and Darnault, C. (2008). Riverbank filtration for drinking water supply. In M. G. Anderson and J. J. McDonnell (Eds.), Encyclopedia of hydrological sciences. Hoboken, NJ: John Wiley and Sons. Part 13.
  • Regnery, J., Lee, J., Kitanidis, P., Illangasekare, T., Sharp, J. O., and Drewes, J. E. (2013). Integration of artificial recharge and recovery systems in urban settings e overcoming current limitations and engineering challenges. Environmental Engineering Science, 30, 409–420.
  • Regnery, J., Wing, A.D., Alidina, M., and Drewes, J. E. (2015a). Biotransformation of trace organic chemicals during groundwater recharge: how useful are first-order rate constants? Journal of Contaminant Hydrology, 179, 65–75.
  • Regnery, J., Barringer, J., Wing, A.D., Hoppe-Jones, C., Teerlink, J., and Drewes, J. E. (2015b). Start-up performance of a full-scale riverbank filtration site regarding removal of DOC, nutrients, and trace organic chemicals. Chemosphere, 127, 136–142.
  • Regnery, J., Wing, A.D., Kautz, J., and Drewes, J. E. (2016). Introducing sequential managed aquifer recharge technology (SMART) – From laboratory to full- scale application. Chemosphere, 154, 8–16.
  • Regnery, J., Lee, J., Drumheller, Z. W., Drewes, J. E., Illangasekare, T. H., Kitanidis, P. K., McCray, J. E., and Smits, K. M. (2017). Trace organic chemical attenuation during managed aquifer recharge: Insights from a variably saturated 2D tank experiment. Journal of Hydrology, 548, 641–651.
  • Richardson, S. D. and Ternes, T. A. (2014). Water analysis: Emerging contaminants and current issues. Analytical Chemistry, 86, 2813–2848.
  • Ringleb, J., Sallwey, J., and Stefan, C. (2016). Assessment of managed aquifer recharge through modeling—A review. Water, 8, 579–609.
  • Rodriguez, R. A., Pepper, I. L., and Gerba, C. P. (2009). Application of PCR-based methods to assess the infectivity of enteric viruses in environmental samples. Applied and Environmental Microbiology, 75, 297–307.
  • Rosario, K., Nilsson, C., Lim, Y. W., Ruan, Y., and Breitbart, M. (2009). Metagenomic analysis of viruses in reclaimed water. Environmental Microbiology, 11, 2806–2820.
  • Sadeghi, G., Schijven, J. F., Behrends, T., Hassanizadeh, S. M., Gerritse, J., and Kleingeld, P. J. (2011). Systematic study of effects of pH and ionic strength on attachment of phage PRD1. Ground Water, 49, 12–19.
  • Sarmah, A. K. and Northcott, G. L. (2008). Laboratory degradation studies of four endocrine disruptors in two environmental media. Environmental Toxicology and Chemistry, 27, 819–827.
  • Sasidharm, S., Torkzaban, S., Bradford, S. S., Cook, P.G, and Gupta, V. V. S. R. (2017). Temperature dependency of virus and nanoparticle transport and retention in saturated porous media. Journal of Contaminate Hydrology, 196, 10–20.
  • Schaffer, M., Bornick, H., Nödler, K., Licha, T., and Worch, E. (2012). Role of cation ex- change processes on the sorption influenced transport of cationic β;-blockers in aquifer sediments. Water Research, 46, 5472–5482.
  • Schijven, J. F., Hoogenbozem, W., Hassanizadeh, S. M., and Peters, J. H. (1999). Modeling removal of bacteriophages MS2 and PRD1 by dune sand recharge at Castricum, Netherlands. Water Resources Research, 35, 1101–1111.
  • Schijven, J. F., Sadeghi, G., and Hassanizadeh, S. M. (2016). Long-term inactivation of bacteriophage PRD1 as a function of temperature, pH, sodium and calcium concentration. Water Research, 103, 66–73.
  • Schmitz, B. W., Kitajima, M., Campillo, M. E., Gerba, C. P., and Pepper, I. L. (2016). Virus reduction during advance bardenpho and conventional wastewater treatment processes. Environmental Science and Technology, 50, 9524–9532.
  • Schönheinz, D. and Grischek, T. (2001). Behavior of dissolved organic carbon during bank filtration under extreme climate conditions. In C., Ray and M., Shamrukh (Eds.), Riverbank filtration for water security in desert countries, (pp. 51–67). Berlin, Germany: Springer.
  • Schymanski, E. L., Jeon, J., Gulde, R., Fenner, K., Ruff, M., Singer, H. P., and Hollender, J. (2014). Identifying small molecules via high resolution mass spectrometry: Communicating confidence. Environmental Science and Technology, 48, 2097–2098.
  • Shareef, A., Page, D., Vanderzalm, J., Williams, M., Gupta, V. V. S. R., Dillon, P., and Kookana, R. (2013). Biodegradation of simazine and diuron herbicides under aerobic and anoxic conditions relevant to managed aquifer recharge of storm water. Clean – Soil, Air, Water, 42, 745–752.
  • Sharma, S. K. and Amy, G. (2011). Natural treatment systems. In J. K. Edzwald (Ed.), Water quality and treatment (pp. 1–33, 6th edition). Denver, CO: American Water Works Association.
  • Sharma, S. K., Chaweza, D., Bosuben, N., Holzbecher, E., and Amy, G. (2012a). Framework for feasibility assessment and performance analysis of riverbank filtration systems for water treatment. Journal of Water Supply: Research and Technology – AQUA, 61, 73–81.
  • Sharma, S. K., Ernst, M., Hein, A., Jekel, M., Jefferson, B., and Amy, G. (2012b). Treatment trains utilising natural and hybrid processes. In C. Kazner, T. Wintgens, and P. Dillon (Eds.), Water reclamation technologies for safe managed aquifer recharge. London, UK: IWA Publishing.
  • Sidhu, J. P. S., Toze, S., Hodgers, L., Shackelton, M., Barry, K., and Page, D. (2010). Pathogen inactivation during passage of stormwater through a constructed reedbed and aquifer transfer, storage and recovery. Anglais, 62, 1190–1197.
  • Sidhu, J. P. S. and Toze, S. (2012). Assessment of pathogen survival potential during managed aquifer recharge with diffusion chambers. Journal of Applied Microbiology, 113, 693–700.
  • Sidhu, J. P. S., Toze, S., Hodgers, L., Barry, K., Page, D., Li, Y., and Dillon, P. (2015). Pathogen decay during managed aquifer recharge at four sites with different geochemical characteristics and recharge water sources. Journal of Environmetal Quality, 44, 1402–1412.
  • Sprenger, C., Lorenzen, G., Hülshoff, I., Grützmacher, G., Ronghang, M., and Pekdeger, A. (2011). Vulnerability of bank filtration systems to climate change. Science of the Total Environment, 409, 655–663.
  • Sprenger, C., Hartog, N., Hernández, M., Vilanova, E., Grützmacher, G., Scheibler, F., and Hannappel, S. (2017). Inventory of managed aquifer recharge sites in Europe: historical development, current situation and perspectives. Hydrogeology Journal, 25, 1909–1922.
  • State Water Board Resolution (2013). Water recycling policy. Sacramento, CA: State Water Resources Control Board.
  • Stefan, C. and Ansems, N. (2016). Web-GIS of global inventory of managed aquifer recharge (MAR) applications. Available online: http://marportal.un-igrac.org.
  • Stepien, D. K., Regnery, J., Merz, C., and Püttmann, W. (2013). Behavior of organophosphates and hydrophilic ethers during bank filtration and their potential application as organic tracers. A field study from the Oderbruch, Germany. Science of the Total Environment, 458–460, 150–159.
  • Stuyfzand, P. J., Segers, W., and van Rooijen, N. (2007). Behavior of pharmaceuticals and other emerging pollutants in various artificial recharge systems in The Netherlands. ISMAR6 – Proceedings of the 6th International Symposium in Managed Aquifer Recharge. p. 231–245.
  • Stuyfzand, P. J. (2011). Riverbank filtration for water security in desert countries. Dordrecht, The Netherlands: Springer Netherlands.
  • Symonds, E. M., Griffin, D. W., and Breitbart, M. (2009). Eukaryotic viruses in wastewater samples from the United States. Applied and Environmental Microbiology, 75, 1402–1409.
  • Tadkaew, N., Hai, F. I., McDonald, J. A., Khan, S. J., and Nghiem, L. D. (2011). Removal of trace organics by MBR treatment: The role of molecular properties. Water Research, 45, 2439–2451.
  • Tandoi, V., Levantesi, C., Toze, S., Böckelmann, U., Divizia, M., Ayuso-Gabella, M. N., Salgot, M., La Mantia, R., and Grohmann, E. (2012). Water quality analysis – microbial hazards. In C. Kazner, T. Wintgens, and P. Dillon (Eds.), Water reclamation technologies for safe managed aquifer recharge. London, UK: IWA Publishing.
  • Teerlink, J., Hering, A., Higgins, C., and Drewes, J. E. (2012). Variability of trace organic chemical concentrations in raw wastewater at three distinct sewershed scales. Water Research, 46, 3261–3271.
  • Toze, S., Bekele, E., Page, D., Sidhu, J., and Shackleton, M. (2010). Use of static quantitative microbial risk assessment to determine pathogen risks in an unconfined carbonate aquifer used for managed aquifer recharge. Water Research, 44, 1038–1049.
  • US EPA (2006). Process design manual: Land treatment of municipal wastewater effluents. Washington, DC: United States Environmental Protection Agency.
  • US EPA (2012). Guidelines for water reuse. Washington, DC: United States Environmental Protection Agency.
  • US EPA (2016a). Fourth Unregulated Contaminant Monitoring Rule. Washington, DC: United States Environmental Protection Agency. (https://www.epa.gov/dwucmr/fourth-unregulated-contaminant-monitoring-rule).
  • US EPA (2016b). Contaminant Candidate List and Regulatory Determination. Washington, DC: United States Environmental Protection Agency. (https://www.epa.gov/ccl/contaminant-candidate-list-4-ccl-4-0).
  • US EPA (2017). TSCA Chemical Substance Inventory. Washington, DC: United States Environmental Protection Agency. (https://www.epa.gov/tsca-inventory).
  • Valhondo, C., Carrera, J., Ayora, C., Barbieri, M., Nödler, K., Licha, T., and Huerta, M. (2014). Behavior of nine selected emerging trace organic contaminants in an artificial recharge system supplemented with a reactive barrier. Environmental Science Pollution Research, 21, 11832–11843.
  • Vione, D., Caringella, R., De Laurentiis, E., Pazzi, M., and Minero, C. (2013). Phototransformation of the sunlight filter benzophenone-3 (2-hydroxy-4-methoxybenzophenone) under conditions relevant to surface waters. Science of the Total Environment, 463–464, 243–251.
  • Washington Department of Health, Washington Department of Ecology (1997). Water Reclamation and Reuse Standards. Olympia, WA: Publication #97-23.
  • Wiese, B., Massmann, G., Jekel, M., Heberer, T., Dünnbier, U., Orlikowski, D., and Grützmacher, G. (2011). Removal kinetics of organic compounds and sum parameters under field conditions for managed aquifer recharge. Water Research, 45, 4939–4950.
  • World Health Organization (2006). WHO Guidelines for the safe use of wastewater, excreta and greywater. 3rd edn. Vol. 2, Wastewater use in agriculture. Geneva, Switzerland: World Health Organization.
  • Yang, Y. J., Neil, C., Neil, J., Goodrich, J. A., Simon, M., Jun, Y., Burnell, D. K., Cohen, R., Schupp, D., and Krishnan, R. (2016). Decision support system for aquifer recharge (AR) and aquifer storage and recovery (ASR) planning, design, and evaluation – principles and technical basis. Cincinnati, OH: United States Environmental Protection Agency Report EPA 600-R-16-222.
  • Ying, G. G., Kookana, R. S., and Dillon, P. (2003). Sorption and degradation of selected five endocrine disrupting chemicals in aquifer material. Water Research, 37, 3785–3791.
  • Ying, G. G. and Kookana, R. S. (2005). Sorption and degradation of estrogen-like endocrine disrupting chemicals in soil. Environmental Toxicology and Chemistry, 24, 2640–2645.
  • Ying, G. G., Yu, X. Y., and Kookana, R. S. (2007). Biological degradation of triclocarban and triclosan in a soil under aerobic and anaerobic conditions and comparison with environmental fate modeling. Environmental Pollution, 150, 300–305.
  • Ying, G. G., Toze, S., Hanna, J., Yu, X. Y., Dillon, P. J., and Kookana, R. S. (2008). Decay of endocrine-disrupting chemicals in aerobic and anoxic groundwater. Water Research, 42, 1133–1141.
  • Yuan, S. Y., Liu, C., Liao, C. S., and Chang, B. V. (2002). Occurrence and microbial degradation of phthalate esters in Taiwan river sediments. Chemosphere, 49, 1295–1299.
  • Yuan, J., Van Dyke, M. I., and Huck, P.M. (2016). Water reuse through managed aquifer recharge (MAR): assessment of regulations/guidelines and case studies. Water Quality Research Journal, 51, 357–376.

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