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Efficiency of Bank Filtration and Post-Treatment

dc.contributor.authorRay, Chittaranjan*
dc.contributor.authorGrischek, Thomas*
dc.date.accessioned2021-02-11T12:10:40Z
dc.date.available2021-02-11T12:10:40Z
dc.date.issued2019*
dc.date.submitted2019-12-09 11:49:15*
dc.identifier42470*
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/45902
dc.description.abstractRiverbank filtration (RBF) schemes for the production of drinking water are increasingly challenged by new constituents of concern, such as organic micropollutants and pathogens in the source water and hydrological flow variations due to weather extremes. RBF and new technology components are integrated and monitoring and operating regimes are adopted to further optimize water treatment in bank filtration schemes for these new requirements. This Special Issue presents results from the EU project AquaNES “Demonstrating synergies in combined natural and engineered processes for water treatment systems” (www.aquanes.eu). Additionally, papers from other research groups cover the efficiency of bank filtration and post-treatment, advantages and limitations of combining natural and engineered processes, parameter-specific assessment of removal rates during bank filtration, and the design and operation of RBF wells. The feasibility, design, and operation of RBF schemes under specific site conditions are highlighted for sites in the US, India, and South Korea*
dc.languageEnglish*
dc.subjectTA1-2040*
dc.subjectT1-995*
dc.subject.classificationthema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technologyen_US
dc.subject.otherfloods*
dc.subject.otherenvironmental monitoring*
dc.subject.otherriver bank filtration*
dc.subject.otherheavy metals*
dc.subject.otherriverside water source*
dc.subject.otherentrance velocity*
dc.subject.otherultrafiltration*
dc.subject.otheronline monitoring*
dc.subject.otherdrinking water treatment*
dc.subject.otherwater treatment*
dc.subject.othersystem costs*
dc.subject.otheroptimization*
dc.subject.otherbiofilm*
dc.subject.otherfluorescence excitation-emission matrix*
dc.subject.otherriverbed*
dc.subject.otherinorganic chemicals*
dc.subject.otherwell structure remodeling*
dc.subject.otherriverbank filtration (RBF)*
dc.subject.othersub-oxic conditions*
dc.subject.otherelectro-chlorination*
dc.subject.otherenergy generation*
dc.subject.otherpressure loss*
dc.subject.otherbank filtrate portion*
dc.subject.otherremoval efficacy*
dc.subject.otherbank filtrate*
dc.subject.othermanganese*
dc.subject.otherout/in membrane comparison*
dc.subject.otherpharmaceutical residues*
dc.subject.otheranalytical method*
dc.subject.otherhydrochemistry*
dc.subject.othersubsurface geology*
dc.subject.otherdissolved organic matter*
dc.subject.othercolumn experiments*
dc.subject.otherstorage tank*
dc.subject.othergroundwater*
dc.subject.otherorganic matter composition*
dc.subject.otherwater supply*
dc.subject.otherrural water supply*
dc.subject.othercollector wells*
dc.subject.othermirror-image method*
dc.subject.othersouthern India*
dc.subject.othergabapentin*
dc.subject.othermicroorganisms*
dc.subject.othersite investigation*
dc.subject.othersmall communities*
dc.subject.otherdecentralized capillary nanofiltration*
dc.subject.otherPHREEQC*
dc.subject.otherrenewable energy*
dc.subject.otherdroughts*
dc.subject.otherhydrological trends*
dc.subject.otherbank filtration*
dc.subject.otherfilter cake*
dc.subject.othersulphate*
dc.subject.otherpoint-bar alluvial setting*
dc.subject.otherinline electrolysis*
dc.subject.otherenergy efficiency*
dc.subject.otherGanga*
dc.subject.otherclimate change*
dc.subject.otherturbine*
dc.subject.otherNakdong River*
dc.subject.otherorganic matter degradation*
dc.subject.otheroxypurinol*
dc.subject.otherslow sand filtration*
dc.subject.othersuboxic*
dc.subject.otherPARAFAC-EEM*
dc.subject.otherKrishna River*
dc.subject.otherwater quality*
dc.subject.othersmart villages*
dc.subject.othermicropollutants*
dc.subject.otheranoxic*
dc.subject.otherdissolved organic carbon (DOC)*
dc.subject.otherattenuation*
dc.subject.otherorganic micropollutants*
dc.subject.otherdisinfection*
dc.subject.othersurface water treatment*
dc.subject.othernitrate*
dc.subject.otherdrinking water hydropower*
dc.subject.otherpesticides*
dc.subject.otherdisinfection by-products*
dc.subject.otherDamodar*
dc.subject.otherpathogen barrier*
dc.subject.otherorganic carbon*
dc.subject.othersalinity*
dc.subject.othersustainable water production*
dc.subject.otherclogging*
dc.subject.otherYamuna*
dc.subject.otherLC-OCD*
dc.subject.otherredox sensitivity*
dc.subject.otherpharmaceuticals*
dc.subject.otherhigh temperature*
dc.subject.otherperformance*
dc.subject.otherriverbank filtration*
dc.subject.othertrihalomethanes*
dc.subject.otheriron*
dc.titleEfficiency of Bank Filtration and Post-Treatment*
dc.typebook
oapen.identifier.doi10.3390/books978-3-03921-306-1*
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0*
oapen.relation.isbn9783039213061*
oapen.relation.isbn9783039213054*
oapen.pages352*
oapen.edition1st*


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