2020
DOI: 10.1002/cplu.202000544
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Studying the Impact of Wall Shear Stress on the Development and Performance of Electrochemically Active Biofilms

Abstract: A laminar flow reactor was designed that provides constant and reproducible growth conditions for the bioelectrochemical observation of electroactive bacteria (EAB). Experiments were performed using four reactors in parallel to enable the comparison of EAB growth behavior and bioelectrochemical performance under different hydrodynamic conditions while simultaneously keeping biological conditions identical. With regard to the moderate flow conditions found in wastewater treatment applications, the wall shear st… Show more

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Cited by 8 publications
(6 citation statements)
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“…[28] It is also doubtful that the observed voltage loss was due to EAB erosion because the shear stress was only (0.5 mPa) at the flow rates until this point, which is well below the values used in previous work. [23,29] The microfluidic MFC was also designed to prevent O2 contamination and ferricyanide crossover to the anolyte flow stream, but we do not rule out accidental contamination during syringe replacement or from slow O2 leaks through faults in the device gas-protection layer, fluid connects or even through the porous graphite electrodes. Other possibilities include biological contamination and metabolically inactive outer layers, as recently reported.…”
Section: Experimental Timeline (Transition To Compromised Performance and Hydrodynamic Interventions)mentioning
confidence: 99%
See 1 more Smart Citation
“…[28] It is also doubtful that the observed voltage loss was due to EAB erosion because the shear stress was only (0.5 mPa) at the flow rates until this point, which is well below the values used in previous work. [23,29] The microfluidic MFC was also designed to prevent O2 contamination and ferricyanide crossover to the anolyte flow stream, but we do not rule out accidental contamination during syringe replacement or from slow O2 leaks through faults in the device gas-protection layer, fluid connects or even through the porous graphite electrodes. Other possibilities include biological contamination and metabolically inactive outer layers, as recently reported.…”
Section: Experimental Timeline (Transition To Compromised Performance and Hydrodynamic Interventions)mentioning
confidence: 99%
“…[39] This may reflect amplified stresses, e.g., those due to flow-enhanced transport of low concentration O2 in solution to the EAB, as other literature examples typically show an increase to power with flow. [29,40]…”
Section: The Role Of Polarization Test Stability In Measurements Featuring Power Overshootmentioning
confidence: 99%
“…In addition, predictable experimental conditions make the microfluidic format ideal for numerical modeling, [12][13][14] which often complements and extrapolates from experimental studies. 9,[15][16][17] Following the reductive approach in successful application of microfluidics to other fields (e.g., organ-on-a-chip, microfluidic bioreactors, etc. ), microfluidic MFCs should aim to maximize simplicity in design and operation in order to focus on essential features or mechanisms.…”
Section: Introductionmentioning
confidence: 99%
“…Keeping in mind, Orlu et al [32] described the study on the fluctuating wall shear stress in zero pressure-gradient turbulent boundary layers flow. Recently, Mob et al [33] present a paper in which they describe the study of the impact of wall-shear stress on the evolution and execution of electrochemically alive biofilm. The author referred to some recent contributions in the field [34][35][36][37].…”
Section: Introductionmentioning
confidence: 99%