Electrode-Based Approach for Monitoring In Situ Microbial Activity During Subsurface Bioremediation

Williams, Kenneth H.; Nevin, Kelly P.; Franks, Ashley E.; Englert, Andreas; Long, Philip E.; Lovley, Derek R.

doi:10.1021/es9017464

Cited by 86 publications

(70 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, taking also the use of plants and possible agricultural practices into account, this study has shown that granular materials can provide a good alternative. MFC-technology has been proposed as a means of alternative or enhanced soil or sediment remediation (Yuan et al 2010;Zhang et al 2010;Williams et al 2010). The idea behind this concept is to provide an extra electron donor or acceptor in the form of an electrode.…”

Section: Microbial Community and Materials Structurementioning

confidence: 99%

Suitability of granular carbon as an anode material for sediment microbial fuel cells

et al. 2012

View full text Add to dashboard Cite

(2012). Suitability of granular carbon as anode material for sediment microbial fuel cells. Journal of Soils and Sediments 12 (7) Materials and methods: Laboratory microcosms with 8 different electrode materials (granules, felts and cloths)were examined with controlled organic matter addition under brackish conditions. Current density, organic matter removal and microbial community composition were monitored using 16S-rRNA gene PCR followed by Denaturing Gradient Gel Electrophoresis (DGGE). The main parameters investigated were the influence of the amount of electrode material applied to the sediment, the size of the granular material and the electrode configuration.Results and discussion: Felt material had an overall superior performance in terms of current density per amount of applied electrode material i.e. felt and granular anode obtained similar current densities (approx. 50-60 mA/m 2 ) but felt materials required 29% less material to be applied. Yet, when growing plants, granular carbon is more suited because it is considered to restore, upon disturbance, the electrical connectivity within the anode compartment. Small granules (0.25-0.5 mm) gave the highest current density compared to larger granules (1-5 mm) of the same material. Granules with a rough surface had a better performance compared to smooth granules of the same size. The different granular materials lead to a selection of distinct microbial communities for each material, as shown by DGGE.Conclusions: Granular carbon is suited as anode material for sediment microbial fuel cells. This opens the perspective for application of MFC in cultivated areas. In a wider context, the application of granular carbon electrodes can also be an option for in-situ bioremediation of contaminated soils.

show abstract

Section: Microbial Community and Materials Structurementioning

confidence: 99%

Suitability of granular carbon as an anode material for sediment microbial fuel cells

et al. 2012

View full text Add to dashboard Cite

show abstract

“…In the field, the electrode spacing seems not so crucial. Results from a sensing probe (graphite anode embedded within a sand pack) for monitoring in situ microbial activity in an aquifer undergoing bioremediation, shows that MFC can produce detectable currents despite long range separation (6 m) between anode and cathode [148]. To overcome spacing issue, several setups are proposed as: tubular setup where the electrodes are separated only by a low-cost cloth and so the cathode catalytic surface (conductive paint + catalyst) inside the tube is directly exposed to air to allow efficient oxygen reduction; or 3D setup with multilayer or honeycomb anode structure.…”

Section: Surface Functionalisationmentioning

confidence: 99%

Bioremediation in Water Environment: Controlled Electro-Stimulation of Organic Matter Self-Purification in Aquatic Environments

Jobin¹,

Namour²

2017

AiM

View full text Add to dashboard Cite

This review describes a new means of control and stimulation of microorganisms involved in the bioremediation of sediments and waterlogged soils. This emerging technology is derived from sedimentary microbial fuel cells, and consists in ensuring aerobic respiration of aerobic microbial populations in anaerobic conditions by means of a fixed potential anode in order to evacuate the electrons coming from the microbial respiratory chains. This review describes the conceptual basis of the electro-bioremediation, the material devices used (electrode set-ups and spacing), and finally studies the various devices published since the bench tests until the scarce in-field implementations.

show abstract

“…An oxygen reduction reaction is not a solution as this will be counterproductive towards mitigation of the eutrophication. However a long distance cathode (Williams et al, 2010) can be used when it is placed on the water surface where there is a lot of photosynthetic oxygen production. Another possibility is to make use of a nitrate reducing biocathode reaction .…”

Section: Outlook and Opportunitiesmentioning

confidence: 99%

Bioreactor technology in marine microbiology: From design to future application

Arends

Wiele

Boon

2011

Biotechnology Advances

View full text Add to dashboard Cite

Marine micro-organisms have been playing highly diverse roles over evolutionary time: they have defined the chemistry of the oceans and atmosphere. During the last decades, bioreactors with novel designs have become an important tool to study marine microbiology and ecology in terms of: marine microorganism cultivation and deep-sea bioprocess characterization; unique bio-chemical product formation and intensification; marine waste treatment and clean energy generation. In this review we briefly summarize the current status of bioreactor technology applied in marine microbiology and the critical parameters to take into account during reactor design. Furthermore, when we look at the growing population, as well as, pollution in the coastal areas of the world, it is urgent to find sustainable practices that beneficially stimulate both the economy and the natural environment. Here we outlook a few possibilities where innovative bioreactor technology can be applied to enhance energy generation and food production without harming the local marine ecosystem.

show abstract

Electrode-Based Approach for Monitoring In Situ Microbial Activity During Subsurface Bioremediation

Cited by 86 publications

References 41 publications

Suitability of granular carbon as an anode material for sediment microbial fuel cells

Suitability of granular carbon as an anode material for sediment microbial fuel cells

Bioremediation in Water Environment: Controlled Electro-Stimulation of Organic Matter Self-Purification in Aquatic Environments

Bioreactor technology in marine microbiology: From design to future application

Contact Info

Product

Resources

About