Shifting to biology promotes highly efficient iron removal in groundwater filters.

Müller, Simon; Corbera-Rubio, Francesc; Schoonenberg Kegel, Frank; Laureni, Michele; van Loosdrecht, Mark C M; van Halem, Doris

Müller, Simon; Corbera-Rubio, Francesc; Schoonenberg Kegel, Frank; Laureni, Michele; van Loosdrecht, Mark C M; van Halem, Doris.

Afiliación

Müller S; Delft University of Technology, the Netherlands. Electronic address: s.muller@tudelft.nl.
Corbera-Rubio F; Delft University of Technology, the Netherlands.
Schoonenberg Kegel F; Vitens N.V., the Netherlands.
Laureni M; Delft University of Technology, the Netherlands.
van Loosdrecht MCM; Delft University of Technology, the Netherlands.
van Halem D; Delft University of Technology, the Netherlands.

Water Res ; 262: 122135, 2024 Sep 15.

Article en En | MEDLINE | ID: mdl-39067270

ABSTRACT

ABSTRACT

Rapid sand filters are established and widely applied technologies for groundwater treatment. In these filters, main groundwater contaminants such as iron, manganese, and ammonium are oxidized and removed. Conventionally, intensive aeration is employed to provide oxygen for these redox reactions. While effective, intensive aeration promotes flocculent iron removal, which results in iron oxide flocs that rapidly clog the filter. In this study, we operated two parallel full-scale sand filters at different aeration intensities to resolve the relative contribution of homogeneous, heterogeneous and biological iron removal pathways, and identify their operational controls. Our results show that mild aeration in the LOW filter (5 mg/L O2, pH 6.9) promoted biological iron removal and enabled iron oxidation at twice the rate compared to the intensively aerated HIGH filter (>10 mg/L O2, pH 7.4). Microscopy images showed distinctive twisted stalk-like iron solids, the biosignatures of Gallionella ferruginea, both in the LOW filter sand coatings as well as in its backwash solids. In accordance, 10 times higher DNA copy numbers of G. ferruginea were found in the LOW filter effluent. Clogging by biogenic iron solids was slower than by chemical iron flocs, resulting in lower backwash frequencies and yielding four times more water per run. Ultimately, our results reveal that biological iron oxidation can be actively controlled and favoured over competing physico-chemical routes. The production of more compact and practically valuable iron oxide solids is of outmost interest. We conclude that, although counterintuitive, slowing down iron oxidation in the water before filtration enables rapid iron removal in the biofilter.

Asunto(s)

Filtración; Agua Subterránea; Hierro; Purificación del Agua; Agua Subterránea/química; Hierro/química; Purificación del Agua/métodos; Contaminantes Químicos del Agua; Gallionellaceae; Oxidación-Reducción

Palabras clave

Aeration; Biofilter; Gallionella; Groundwater; Iron oxides; Sand filter

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Texto completo: 1 Colección: 01-internacional Base de datos: MEDLINE Asunto principal: Agua Subterránea / Purificación del Agua / Filtración / Hierro Idioma: En Revista: Water Res Año: 2024 Tipo del documento: Article Pais de publicación: Reino Unido

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