Using kinetics and modeling to predict denitrification fluxes in elemental‐sulfur‐based biofilms

Wang, Yue; Sabba, Fabrizio; Bott, Charles; Nerenberg, Robert

doi:10.1002/bit.27094

Cited by 23 publications

(4 citation statements)

References 59 publications

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“…Biofilm growth/decay in the short and long term, and the impact of the biofilm thickness on denitrification efficiency and current demand should also be kept in consideration as substrate diffusion in the biofilm may greatly affect the denitrification process. 50,51 Perchlorate is often concomitant with NO 3 − in groundwater, has a similar reduction potential (0.75 for NO 3 − /N 2 and 0.87 for ClO 4 − /Cl), and may compete for electrons in biocathodic denitrification: 52 the presence of an additional TEA may strongly influence the denitrification kinetics also due to the different optimal pH for reduction Environmental Science: Water Research & Technology Paper overall denitrification process; similar findings were reported by Clauwaert et al 53 for denitrifying biocathodes in MFCs.…”

Section: Limits Of the Model And Perspectivesmentioning

confidence: 99%

Integrated experimental and modeling evaluation of removal efficiency and energy consumption for an autotrophic denitrifying biocathode

Cecconet¹,

Sabba²,

Anastasi³

et al. 2022

Environ. Sci.: Water Res. Technol.

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Section: Limits Of the Model And Perspectivesmentioning

confidence: 99%

Integrated experimental and modeling evaluation of removal efficiency and energy consumption for an autotrophic denitrifying biocathode

Cecconet¹,

Sabba²,

Anastasi³

et al. 2022

Environ. Sci.: Water Res. Technol.

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“…The nucleophilic attack between sulfide (S 2− ) and S 0 under neutral or alkaline conditions results in the cleavage of S 8 0 rings and the formation of polysulfide (S n 2− ) as detailed in Equation ( 2) [20]. This chemical reaction has received much attention due to the higher solubility and bioavailability of S n 2− [20,28,29]. Therefore, the polysulfide-involved SADN (PiSADN) process (Equation (3)) might be an effective method for realizing high-rate NO 3 − removal.…”

Section: Introductionmentioning

confidence: 99%

Improved Performance of Sulfur-Driven Autotrophic Denitrification Process by Regulating Sulfur-Based Electron Donors

Xu,

Lu,

et al. 2024

Water

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Sulfur-driven autotrophic denitrification (SADN) has demonstrated efficacy in nitrate (NO3−) removal from the aquatic environment. However, the insolubility of elemental sulfur (S0) (maximum 5 μg/L at 25 °C) limited the NO3− removal rate. In this study, we investigated the performance of a laboratory-scale S0-packed bed reactor (S0-PBR) under various volumetric NO3− loading rates. By filling with smaller S0 particles (0.5–1 mm) and introducing chemical sulfide (30–50 mg S2−-S/L), a high NO3− removal rate (1.44 kg NO3−-N/(m3·d)) was achieved, which was substantially higher than previously reported values in SADN systems. The analysis of the average specific NO3− removal rates and the half-order kinetic constants jointly confirmed that the denitrification performance was significantly enhanced by decreasing the S0 particle sizes from 10–12 mm to 1–2 mm. The smaller S0 particles with a larger specific surface area improved the mass-transfer efficiency. Dosing chemical S2− (20 mg S2−-S/L) to trigger the abiotic polysulfuration process increased the specific NO3− removal rate from 0.366 to 0.557 g NO3−-N/g VSS/h and decreased the portion of removed NO3−-N in the form of nitrous oxide (N2O-N) from 1.6% to 0.7% compared to the S2−-free group.

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“…In this framework, mathematical modelling is a useful tool to elucidate the competition among different microbial families and the performances in terms of nitrate removal and sulfate production occurring during the SdAD process. Indeed, previous mathematical models with elemental sulfur as electron donor have been mainly focused on evaluating the kinetics of the process in terms of nitrate removal 20 – 22 , nitrite accumulation 5 and N 2 O emission 23 , 24 . In addition, the co-occurrence of SdAD and heterotrophic denitrification 17 , 25 has been also modelled to investigate the same parameters.…”

Section: Introductionmentioning

confidence: 99%

Modelling the effect of SMP production and external carbon addition on S-driven autotrophic denitrification

Guerriero¹,

Mattei²,

Papirio

et al. 2022

Sci Rep

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The aim of this study was to develop a mathematical model to assess the effect of soluble microbial products production and external carbon source addition on the performance of a sulfur-driven autotrophic denitrification (SdAD) process. During SdAD, the growth of autotrophic biomass (AUT) was accompanied by the proliferation of heterotrophic biomass mainly consisting of heterotrophic denitrifiers (HD) and sulfate-reducing bacteria (SRB), which are able to grow on both the SMP derived from the microbial activities and on an external carbon source. The process was supposed to occur in a sequencing batch reactor to investigate the effects of the COD injection on both heterotrophic species and to enhance the production and consumption of SMP. The mathematical model was built on mass balance considerations and consists of a system of nonlinear impulsive differential equations, which have been solved numerically. Different simulation scenarios have been investigated by varying the main operational parameters: cycle duration, day of COD injection and quantity of COD injected. For cycle durations of more than 15 days and a COD injection after the half-cycle duration, SdAD represents the prevailing process and the SRB represent the main heterotrophic family. For shorter cycle duration and COD injections earlier than the middle of the cycle, the same performance can be achieved increasing the quantity of COD added, which results in an increased activity of HD. In all the performed simulation even in the case of COD addition, AUT remain the prevailing microbial family in the reactor.

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Using kinetics and modeling to predict denitrification fluxes in elemental‐sulfur‐based biofilms

Cited by 23 publications

References 59 publications

Integrated experimental and modeling evaluation of removal efficiency and energy consumption for an autotrophic denitrifying biocathode

Integrated experimental and modeling evaluation of removal efficiency and energy consumption for an autotrophic denitrifying biocathode

Improved Performance of Sulfur-Driven Autotrophic Denitrification Process by Regulating Sulfur-Based Electron Donors

Modelling the effect of SMP production and external carbon addition on S-driven autotrophic denitrification

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