Treating Water by Degrading Oxyanions Using Metallic Nanostructures

Yin, Y. Ben; Guo, Sujin; Heck, Kimberly N.; Clark, Chelsea A.; Coonrod, Christian L.; Wong, Michael S.

doi:10.1021/acssuschemeng.8b02070

Cited by 61 publications

(66 citation statements)

References 173 publications

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“…As documented in other articles in this issue, many water contaminants are oxyanions (Kumar et al, 2014; Yin et al, 2018). Sources include agriculture, mining, metal-working and aerospace industries, municipal wastewater, and natural minerals.…”

Section: Introductionmentioning

confidence: 61%

“…Compared to physical and chemical approaches, mainly including adsorption (Hiemstra and Van Riemsdijk, 1999; Cumberland and Strouse, 2002; Peak, 2006) and catalytic reduction (Chaplin et al, 2012; Yin et al, 2018), microbiological reduction is an effective, economic, and sustainable means to simultaneously remove oxyanions from water. In microbial reduction, the oxyanion regularly functions as a respiratory electron acceptor for bacteria (Rittmann and McCarty, 2001; Martin and Nerenberg, 2012; Madigan et al, 2014; Rittmann, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Hydrogenotrophic Microbial Reduction of Oxyanions With the Membrane Biofilm Reactor

et al. 2019

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Oxyanions, such as nitrate, perchlorate, selenate, and chromate are commonly occurring contaminants in groundwater, as well as municipal, industrial, and mining wastewaters. Microorganism-mediated reduction is an effective means to remove oxyanions from water by transforming oxyanions into harmless and/or immobilized forms. To carry out microbial reduction, bacteria require a source of electrons, called the electron-donor substrate. Compared to organic electron donors, H2 is not toxic, generates minimal secondary contamination, and can be readily obtained in a variety of ways at reasonable cost. However, the application of H2 through conventional delivery methods, such as bubbling, is untenable due to H2's low water solubility and combustibility. In this review, we describe the membrane biofilm reactor (MBfR), which is a technological breakthrough that makes H2 delivery to microorganisms efficient, reliable, and safe. The MBfR features non-porous gas-transfer membranes through which bubbleless H2 is delivered on-demand to a microbial biofilm that develops naturally on the outer surface of the membranes. The membranes serve as an active substratum for a microbial biofilm able to biologically reduce oxyanions in the water. We review the development of the MBfR technology from bench, to pilot, and to commercial scales, and we elucidate the mechanisms that control MBfR performance, particularly including methods for managing the biofilm's structure and function. We also give examples of MBfR performance for cases of treating single and co-occurring oxyanions in different types of contaminated water. In summary, the MBfR is an effective and reliable technology for removing oxyanion contaminants by accurately providing a biofilm with bubbleless H2 on demand. Controlling the H2 supply in accordance to oxyanion surface loading and managing the accumulation and activity of biofilm are the keys for process success.

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Section: Introductionmentioning

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Hydrogenotrophic Microbial Reduction of Oxyanions With the Membrane Biofilm Reactor

et al. 2019

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“…Nevertheless the use of catalysis for the control of water pollutants is not easy because for a commercial use, the catalyst must be active at room temperature and atmospheric pressure and must be very stable avoiding metal leaching. Even this, many papers studied the use of catalytic hydrogenation for the control of some water pollutants as halogenated organics, nitrosamines, nitrate, nitrite and bromate [8–13] …”

Section: Introductionmentioning

confidence: 99%

“…The authors have proposed a mechanism for the bromate reduction involving reactions in the liquid phase and on the surface of the catalyst [29] . A very interesting review [13] describing the use of metallic nanostructures for treating water by degradation of oxyanions has recently appeared, presenting a summary of different catalysts used for the catalytic reduction of bromate.…”

Section: Introductionmentioning

confidence: 99%

The Influence of the Support Nature and the Metal Precursor in the Activity of Pd‐based Catalysts for the Bromate Reduction Reaction

et al. 2021

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Palladium catalysts supported on different materials (alumina, activated carbon and mixed oxide derived from hydrotalcite) and prepared with different metal precursors (nitrate, chloride and acetate) have been characterized and tested for the bromate reduction reaction. The catalytic behavior depends on the support nature and on the metallic precursor used for the catalyst preparation. Pd catalyst supported on a mixed oxide has a low activity due to the high affinity of the reconstructed support for the Br− formed, preventing the reactants to approximate the active Pd sites. Pd catalyst supported on activated carbon has a surface negative charge and a microporous structure, making difficult the interaction of the active sites with the reactants. The best results are obtained with the catalyst supported on alumina due to its physical‐chemical properties, i. e. mesoporosity, positive surface charge and reversible adsorption of reactants and products. These characteristics make easy bromate and H2 adsorption on the active sites and subsequent reaction, thus resulting in a better activity. The Pd precursor salt also influences the catalytic activity as it has an effect on the Pd nanocrystal size. The best results are obtained with the metal precursor that produces homogeneous and large Pd metallic crystallites.

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“…This is a term for a whole series of different chemical processes initiated or mediated by the presence of the catalyst. There are many different classes of catalytic activity which have been reported for nanomaterials in relation to removal of contaminants from water such as photocatalysis [20], reduction [21] and catalysis of the activation of oxidant species [22].…”

mentioning

confidence: 99%

Recent Advances in Magnetic Nanoparticles and Nanocomposites for the Remediation of Water Resources

Govan

2020

Magnetochemistry

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Water resources are of extreme importance for both human society and the environment. However, human activity has increasingly resulted in the contamination of these resources with a wide range of materials that can prevent their use. Nanomaterials provide a possible means to reduce this contamination, but their removal from water after use may be difficult. The addition of a magnetic character to nanomaterials makes their retrieval after use much easier. The following review comprises a short survey of the most recent reports in this field. It comprises five sections, an introduction into the theme, reports on single magnetic nanoparticles, magnetic nanocomposites containing two of more nanomaterials, magnetic nanocomposites containing material of a biologic origin and finally, observations about the reported research with a view to future developments. This review should provide a snapshot of developments in what is a vibrant and fast-moving area of research.

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Treating Water by Degrading Oxyanions Using Metallic Nanostructures

Cited by 61 publications

References 173 publications

Hydrogenotrophic Microbial Reduction of Oxyanions With the Membrane Biofilm Reactor

Hydrogenotrophic Microbial Reduction of Oxyanions With the Membrane Biofilm Reactor

The Influence of the Support Nature and the Metal Precursor in the Activity of Pd‐based Catalysts for the Bromate Reduction Reaction

Recent Advances in Magnetic Nanoparticles and Nanocomposites for the Remediation of Water Resources

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