Assessing microbial competition in a hydrogen‐based membrane biofilm reactor (MBfR) using multidimensional modeling

Martin, Kelly J.; Picioreanu, Cristian; Nerenberg, Robert

doi:10.1002/bit.25607

Cited by 32 publications

(11 citation statements)

References 41 publications

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“…These findings demonstrated the importance of H 2 supply as a control strategy in operating this single-stage H 2 -based MBfR. As shown in Figure 4B, a too low L H2 would suppress the SO 4 2reduction but compromise the removal of ClO 4 and NO 3 -, while a too high L H2 not only meant energy wastage but also triggered the SO 4 2reduction which agreed with the findings of Martin et al [31]. Under the operating conditions of Scenario 2, a L H2 of around 0.114 g COD m -2 h -2 could be considered most suitable.…”

Section: Key Factors Affecting the Single-stage H 2 -Based Mbfrsupporting

confidence: 89%

“…Overall, a thin biofilm (e.g., L f of 50 and 75 µm in this case) was beneficial for the highlevel simultaneous removal of ClO 4 and NO 3 through supporting the coexistence of HDB, PRB, and HB in the biofilm, as shown in Figure 4D. In contrast, a thick biofilm (e.g., L f of more than 100 µm in this case) provided favourable environment and protected space (i.e., inner layer of the biofilm) for SRB, stimulated their growth [31], and therefore compromised the biomass fractions of HDB and PRB in the biofilm, resulting in the increasing SO…”

Section: Key Factors Affecting the Single-stage H 2 -Based Mbfrmentioning

confidence: 56%

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Perchlorate, nitrate, and sulfate reduction in hydrogen-based membrane biofilm reactor: Model-based evaluation

Chen

Liu

Peng

et al. 2017

Chemical Engineering Journal

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Section: Key Factors Affecting the Single-stage H 2 -Based Mbfrsupporting

confidence: 89%

Section: Key Factors Affecting the Single-stage H 2 -Based Mbfrmentioning

confidence: 56%

Perchlorate, nitrate, and sulfate reduction in hydrogen-based membrane biofilm reactor: Model-based evaluation

Chen

Liu

Peng

et al. 2017

Chemical Engineering Journal

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“…Amplicon sequencing of planktonic and surface-attached populations revealed a community structure dominated by fermentative and sulfate-respiring organisms in both instances. Anaerobic biofilms are often stratified, with more favorable electron-accepting processes closer to the surface (Sun et al, 2014; Martin et al, 2015); in our system, a lack of alternative electron-accepting processes likely resulted in a heterogeneous, mixed structure. Sequencing data confirmed the inhibition of SRM.…”

Section: Resultsmentioning

confidence: 96%

Resistance and Resilience of Sulfidogenic Communities in the Face of the Specific Inhibitor Perchlorate

et al. 2019

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Hydrogen sulfide is a toxic and corrosive gas, produced by the activity of sulfate-reducing microorganisms (SRM). Owing to the environmental, economic and human-health consequences of sulfide, there is interest in developing specific inhibitors of SRM. Recent studies have identified perchlorate as a promising emerging inhibitor. The aim of this work is to quantitatively dissect the inhibitory dynamics of perchlorate. Sulfidogenic mixed continuous-flow systems were treated with perchlorate. SRM number, sulfide production and community structure were monitored pre-, during and post-treatment. The data generated was compared to a simple mathematical model, where SRM growth slows as a result of inhibition. The experimental data supports the interpretation that perchlorate largely acts to suppress SRM growth rates, rendering planktonic SRM increasingly susceptible to wash-out. Surface-attachment was identified as an important parameter preventing SRM wash-out and thus governing inhibitory dynamics. Our study confirmed the lesser depletion of surface-attached SRM as compared to planktonic SRM during perchlorate treatment. Indirect effects of perchlorate (bio-competitive exclusion of SRM by dissimilatory perchlorate-reducing bacteria, DPRB) were also assayed by amending reactors with DPRB. Indeed, low concentrations of perchlorate coupled with DRPB amendment can drive sulfide concentrations to zero. Further, inhibition in a complex community was compared to that in a pure culture, highlighting similarities and differences between the two scenarios. Finally, we quantified susceptibility to perchlorate across SRM in various culture conditions, showing that prediction of complex behavior in continuous systems from batch results is possible. This study thus provides an overview of the sensitivity of sulfidogenic communities to perchlorate, as well as mechanisms underlying these patterns.

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“…When H 2 is supplied from the base of the biofilm and O 2 and NO3- from the bulk, opportunities increase for O 2 -sensitive microbes such as sulfate- and selenate-reducing bacteria, dechlorinating Dehalococcoides , acetogens, and methanogens to proliferate near the base of the biofilm. This occurs because the base of the MBfR biofilm has low concentrations of O 2 and NO3-, but a high concentration of H 2 (Martin et al, 2015).…”

Section: The Membrane Biofilm Reactor (Mbfr)mentioning

confidence: 99%

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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Assessing microbial competition in a hydrogen‐based membrane biofilm reactor (MBfR) using multidimensional modeling

Cited by 32 publications

References 41 publications

Perchlorate, nitrate, and sulfate reduction in hydrogen-based membrane biofilm reactor: Model-based evaluation

Perchlorate, nitrate, and sulfate reduction in hydrogen-based membrane biofilm reactor: Model-based evaluation

Resistance and Resilience of Sulfidogenic Communities in the Face of the Specific Inhibitor Perchlorate

Hydrogenotrophic Microbial Reduction of Oxyanions With the Membrane Biofilm Reactor

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