{"id":143,"date":"2022-01-11T01:58:23","date_gmt":"2022-01-11T01:58:23","guid":{"rendered":"https:\/\/books.gw-project.org\/groundwater-microbiology\/?post_type=part&p=143"},"modified":"2022-01-13T05:15:37","modified_gmt":"2022-01-13T05:15:37","slug":"references","status":"publish","type":"part","link":"https:\/\/books.gw-project.org\/groundwater-microbiology\/part\/references\/","title":{"raw":"9 References","rendered":"9 References"},"content":{"raw":"
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Anderson, C.R., R.E. James, E.C. Fru, C.B. Kennedy, and K. Pedersen, 2006, In situ ecological development of a bacteriogenic iron oxide-producing microbial community from a subsurface granitic rock environment. Geobiology, volume 4, issue 1, pages 29-42, doi: <\/span>10.1111\/j.1472-4669.2006.00066.x<\/span><\/a>.<\/p>\r\n

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Bonte, M., B.M. van Breukelen, and P.J. Stuyfzand, 2013b, Temperature-induced impacts on groundwater quality and arsenic mobility in anoxic aquifer sediments used for both drinking water and shallow geothermal energy production. Water Research, volume 47, issue 14, pages 5088-5100, doi: <\/span>10.1016\/j.watres.2013.05.049<\/span><\/a>.<\/p>\r\n

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Chandra, S., R. Sharma, K. Singh, and A. Sharma, 2013, Application of bioremediation technology in the environment contaminated with petroleum hydrocarbon. Annals of Microbiology, volume 63, pages 417-431, doi: <\/span>10.1007\/s13213-012-0543-3<\/span><\/a>.<\/p>\r\n

Chanyi, R.M. and S.F. Koval, 2014, Role of type IV pili in predation by Bdellovibrio bacteriovorus.<\/em> PLoS ONE volume 9, issue 11, page e113404, doi: <\/span>10.1371\/journal.pone.0113404<\/span><\/a>.<\/p>\r\n

Chapelle, F. H., 2000, The significance of microbial processes in hydrogeology and geochemistry. Hydrogeology Journal, volume 8, pages 41-46, doi: <\/span>10.1007\/PL00010973<\/span><\/a>.<\/p>\r\n

Christensen, T.H., P.L. Bjerg, and P. Kjeldsen, 2000, Natural attenuation: a feasible approach to remediation of ground water pollution at landfills? Ground Water Monitoring and Remediation, volume 20, number 1, pages 69-77, doi: <\/span>10.1111\/j.1745-6592.2000.tb00253.x<\/span><\/a>.<\/p>\r\n

Colwell, F.S. and S. D\u2019Hondt, 2013, Nature and extent of the deep biosphere. Reviews in Mineralogy and Geochemistry, volume 75, number 1, pages 547-574, doi: <\/span>10.2138\/rmg.2013.75.17<\/span><\/a>.<\/p>\r\n

Edwards, B.A., V.L. Shirokova, A.M.L. Enright, and F.G. Ferris, 2018. Dependence of in situ bacterial Fe(II)-oxidation and Fe(III)-precipitation on sequential reactive transport. Geomicrobiology Journal, 2018, volume 35, issue 6, pages 503-510, doi: <\/span>10.1080\/01490451.2017.1394929<\/span><\/a>.<\/p>\r\n

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Eltarahony, M., S. Zaki, and D. Abd-El-Haleem, 2020, Aerobic and anaerobic removal of lead and mercury via calcium carbonate precipitation mediated by statistically optimized nitrate reductases. Scientific Reports, volume 10, number 4029, doi: 10.1038\/s41598-020-60951-1<\/span><\/a>.<\/p>\r\n

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Enright, A.M.L. and F.G. Ferris, 2016, Bacterial Fe(II)-oxidation distinguished by long-range correlation in redox potential. Journal of Geophysical Research \u2013 Biogeosciences, volume 121, issue 5, pages 1249-1257, doi: <\/span>10.1002\/2015JG003306<\/span><\/a>.<\/p>\r\n

Enright, A.M.L., B.A. Edwards, and F.G. Ferris, 2019, Long range correlation in redox potential fluctuations signals energetic efficiency of bacterial Fe(II) oxidation. Scientific Reports, volume 9, issue 1, number 4018, doi: <\/span>10.1038\/s41598-019-40499-5<\/span><\/a>.<\/p>\r\n

Falkowski, P.G., T. Fenchel, and E.F. Delong, 2008, The microbial engines that drive Earth's biogeochemical cycles. Science, volume 320, issue 5879, pages 1034-1039, doi: <\/span>10.1126\/science.1153213<\/span><\/a>.<\/p>\r\n

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Ferris, F.G., V.R. Phoenix, Y. Fujita, and R.W. Smith, 2004, Kinetics of calcite precipitation induced by ureolytic bacteria at 10 to 20\u00b0C in artificial groundwater. Geochimica et Cosmochimica Acta, volume 68, issue 8, pages 1701-1710, doi: <\/span>10.1016\/S0016-7037(03)00503-9<\/span><\/a>.<\/p>\r\n

Fortin, D., F.G. Ferris, and T.J. Beveridge, 1997, Surface-mediated mineral development by bacteria. Reviews in Mineralogy and Geochemistry, volume 35, doi: <\/span>10.1515\/9781501509247-007<\/span><\/a>.<\/p>\r\n

Fujita, Y., F.G. Ferris, R. D. Lawson, F. S. Colwell, and R. W. Smith, 2000, Subscribed content calcium carbonate precipitation by ureolytic subsurface bacteria. Geomicrobiology Journal, volume 17, issue 4, pages 305-318, doi: <\/span>10.1080\/782198884<\/span><\/a>.<\/p>\r\n

Genin, J-M., P. Refait, G. Bourrie, M. Abdelmoula, and F. Trolard, 2001, Structure and stability of the Fe(II)-Fe(III) green rust \u201cfougerite\u201d mineral and its potential for reducing pollutants in soil solutions. Applied Geochemistry, volume 16, issue 5, pages 559-570, doi: <\/span>10.1016\/S0883-2927(00)00043-3<\/span><\/a>.<\/p>\r\n

Gleeson, T., K.M. Befus, S. Jasechko, E. Luijendijk, and M.B. Cardenas, 2015, The global volume and distribution of modern groundwater. Nature Geoscience, volume 9, pages 161-169, doi: <\/span>10.1038\/ngeo2590<\/span><\/a>.<\/p>\r\n

Glynn, P.D. and L.N. Plummer, 2005, Geochemistry and the understanding of ground-water systems. Hydrogeology Journal, volume 13, pages 263-287, doi: <\/span>10.1007\/s10040-004-0429-y<\/span><\/a>.<\/p>\r\n

Gorra, R., G. Webster, M. Martin, L. Celi, F. Mapelli, and A.J. Weightman, 2012, Dynamic microbial community associated with iron-arsenic co-precipitation products from a groundwater storage system in Bangladesh. Microbial Ecology, volume 64, issue 1, pages 171-186, doi: <\/span>10.1007\/s00248-012-0014-1<\/span><\/a>.<\/p>\r\n

Groffman, A.R. and L.J. Crossey, 1999, Transient redox regimes in a shallow alluvial aquifer. Chemical Geology, volume 161, issue 4, pages 415-442, doi: <\/span>10.1016\/S0009-2541(99)00119-9<\/span><\/a>.<\/p>\r\n

Hao, L., J. Li, A. Kappler, and M. Obst, 2013, Mapping of heavy metal ion sorption to cell-extracellular polymeric substance-mineral aggregates by using metal-selective fluorescent probes and confocal laser scanning microscopy. Applied and Environmental Microbiology, volume 79, issue 21, pages 6524-6534, doi: <\/span>10.1128\/aem.02454-13<\/span><\/a>.<\/p>\r\n

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Hopkins, G.D., L. Semprini, and P.L. McCarty, 1993, Microcosm and in situ field studies of enhanced biotransformation of trichloroethylene by phenol-utilizing microorganisms. Applied and Environmental Microbiology, volume 59, number 7, pages 2277-2285, doi: <\/span>10.1128\/aem.59.7.2277-2285.1993<\/span><\/a>.<\/p>\r\n

Jack, T.R., L.G. Stehmeier, M.R. Islam, and F.G. Ferris, 1991, Microbial selective plugging to control water channeling. Developments in Petroleum Science, volume 31, pages 433-440, doi: <\/span>10.1016\/S0376-7361(09)70176-1<\/span><\/a>.<\/p>\r\n

Jack, T.R., F.G. Ferris, L.G. Stehmeier, A. Kantzas, and D.F. Marentette, 1993, Bug Rock: bacteriogenic mineral precipitation systems for oil patch use. Developments in Petroleum Science, volume 39, pages 27-35, doi: <\/span>10.1016\/S0376-7361(09)70047-0<\/span><\/a>.<\/p>\r\n

Janssen D.B. and G. Stucki, 2020, Perspectives of genetically engineered microbes for groundwater bioremediation. Environmental Science: Processes & Impacts, volume 22, issue 3, pages 487-499, doi: 10.1039\/c9em00601j<\/a>.<\/p>\r\n

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Kennedy, C.B., A.G. Gault, I.D. Clark, D. Fortin, and F.G. Ferris, 2011, Retention of iodide by bacteriogenic iron oxides. Geomicrobiology Journal, volume 28, issue 5-6, pages 387-395, doi: <\/span>10.1080\/01490451003653110<\/span><\/a>.<\/p>\r\n

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