Comprehensive modeling of a microbial fuel cell

Tsutomu Shimotori; Enrico Marsili; Daniel R. Bond; Edward L. Cussler; Timothy M. LaPara; Raymond M. Hozalski

Comprehensive modeling of a microbial fuel cell

Tsutomu Shimotori, Enrico Marsili, Daniel R. Bond, Edward L. Cussler, Timothy M. LaPara, Raymond M. Hozalski

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

Bacteria consume electron donors (fuel) which are oxidized to gain energy. This electrochemical reaction and the reduction of terminal electron acceptors typically occur inside the bacterial cells. Microbial fuel cells with a membrane-electrode assembly were modeled under quasi-steady state and non-steady state conditions. The model assumed the presence of a thin biofilm on the anode surface, a diffusion boundary layer, diffusion and consumption of the electron donor in the biofilm, and cross-over of the electron donor through the membrane. The model was based on fundamental theories of mass transfer, electron transfer, and microbial respiration. The results of the modeling explain trends in the experimental data, provide direction for future experiments, and give insights into more efficient MFC designs and operational strategies. This is an abstract of a paper presented at the 2006 AIChE Annual Meeting (San Francisco, CA 11/12-17/2006).

Original language	English
Title of host publication	2006 AIChE Annual Meeting
Publication status	Published - 2006
Externally published	Yes
Event	2006 AIChE Annual Meeting - San Francisco, CA, United States Duration: 12 Nov 2006 → 17 Nov 2006

Publication series

Name	AIChE Annual Meeting, Conference Proceedings

Conference

Conference	2006 AIChE Annual Meeting
Country/Territory	United States
City	San Francisco, CA
Period	12/11/06 → 17/11/06

ASJC Scopus subject areas

Biotechnology
General Chemical Engineering
Bioengineering
Safety, Risk, Reliability and Quality

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

@inproceedings{65a62fb9cf0345b8becb3de6e03e919c,

title = "Comprehensive modeling of a microbial fuel cell",

abstract = "Bacteria consume electron donors (fuel) which are oxidized to gain energy. This electrochemical reaction and the reduction of terminal electron acceptors typically occur inside the bacterial cells. Microbial fuel cells with a membrane-electrode assembly were modeled under quasi-steady state and non-steady state conditions. The model assumed the presence of a thin biofilm on the anode surface, a diffusion boundary layer, diffusion and consumption of the electron donor in the biofilm, and cross-over of the electron donor through the membrane. The model was based on fundamental theories of mass transfer, electron transfer, and microbial respiration. The results of the modeling explain trends in the experimental data, provide direction for future experiments, and give insights into more efficient MFC designs and operational strategies. This is an abstract of a paper presented at the 2006 AIChE Annual Meeting (San Francisco, CA 11/12-17/2006).",

author = "Tsutomu Shimotori and Enrico Marsili and Bond, {Daniel R.} and Cussler, {Edward L.} and LaPara, {Timothy M.} and Hozalski, {Raymond M.}",

year = "2006",

language = "English",

isbn = "081691012X",

series = "AIChE Annual Meeting, Conference Proceedings",

booktitle = "2006 AIChE Annual Meeting",

note = "2006 AIChE Annual Meeting ; Conference date: 12-11-2006 Through 17-11-2006",

}

TY - GEN

T1 - Comprehensive modeling of a microbial fuel cell

AU - Shimotori, Tsutomu

AU - Marsili, Enrico

AU - Bond, Daniel R.

AU - Cussler, Edward L.

AU - LaPara, Timothy M.

AU - Hozalski, Raymond M.

PY - 2006

Y1 - 2006

N2 - Bacteria consume electron donors (fuel) which are oxidized to gain energy. This electrochemical reaction and the reduction of terminal electron acceptors typically occur inside the bacterial cells. Microbial fuel cells with a membrane-electrode assembly were modeled under quasi-steady state and non-steady state conditions. The model assumed the presence of a thin biofilm on the anode surface, a diffusion boundary layer, diffusion and consumption of the electron donor in the biofilm, and cross-over of the electron donor through the membrane. The model was based on fundamental theories of mass transfer, electron transfer, and microbial respiration. The results of the modeling explain trends in the experimental data, provide direction for future experiments, and give insights into more efficient MFC designs and operational strategies. This is an abstract of a paper presented at the 2006 AIChE Annual Meeting (San Francisco, CA 11/12-17/2006).

AB - Bacteria consume electron donors (fuel) which are oxidized to gain energy. This electrochemical reaction and the reduction of terminal electron acceptors typically occur inside the bacterial cells. Microbial fuel cells with a membrane-electrode assembly were modeled under quasi-steady state and non-steady state conditions. The model assumed the presence of a thin biofilm on the anode surface, a diffusion boundary layer, diffusion and consumption of the electron donor in the biofilm, and cross-over of the electron donor through the membrane. The model was based on fundamental theories of mass transfer, electron transfer, and microbial respiration. The results of the modeling explain trends in the experimental data, provide direction for future experiments, and give insights into more efficient MFC designs and operational strategies. This is an abstract of a paper presented at the 2006 AIChE Annual Meeting (San Francisco, CA 11/12-17/2006).

UR - http://www.scopus.com/inward/record.url?scp=58049127082&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:58049127082

SN - 081691012X

SN - 9780816910120

T3 - AIChE Annual Meeting, Conference Proceedings

BT - 2006 AIChE Annual Meeting

T2 - 2006 AIChE Annual Meeting

Y2 - 12 November 2006 through 17 November 2006

ER -

Comprehensive modeling of a microbial fuel cell

Abstract

Publication series

Conference

ASJC Scopus subject areas

UN SDGs

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