The yield and decay coefficients of exoelectrogenic bacteria in bioelectrochemical systems

Accepted Manuscript The yield and decay coefficients of exoelectrogenic bacteria in bioelectrochemical systems Erica L. Wilson, Younggy Kim PII:

S0043-1354(16)30113-0

DOI:

10.1016/j.watres.2016.02.054

Reference:

WR 11870

To appear in:

Water Research

Received Date: 1 December 2015 Revised Date:

25 February 2016

Accepted Date: 26 February 2016

Please cite this article as: Wilson, E.L., Kim, Y., The yield and decay coefficients of exoelectrogenic bacteria in bioelectrochemical systems, Water Research (2016), doi: 10.1016/j.watres.2016.02.054. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

pH = 9 &  anode = −0.1 V vs. SHE

Bioelectrochemical systems

Cell yield

Organic  substrate

Exoelectrogen

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Cathode

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Bioanode

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pH = 5 &  anode = −0.3 V vs. SHE Cell yield

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Submitted to: Water Research Date of submission: Feb. 25, 2016 (Original submission: Nov. 28, 2015)

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Erica L. Wilson & Younggy Kim*

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Department of Civil Engineering, McMaster University 1280 Main St. W., JHE 301, Hamilton, Ontario, L8S 4L7, Canada *corresponding author: [email protected]; 1-905-525-9140 ext.24802

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The yield and decay coefficients of exoelectrogenic bacteria in bioelectrochemical systems

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Abstract

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In conventional wastewater treatment, waste sludge management and disposal contribute the

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major cost for wastewater treatment. Bioelectrochemical systems, as a potential alternative for

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future wastewater treatment and resources recovery, are expected to produce small amounts of

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waste sludge because exoelectrogenic bacteria grow on anaerobic respiration and form highly

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populated biofilms on bioanode surfaces. While waste sludge production is governed by the yield

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and decay coefficient, none of previous studies have quantified these kinetic constants for

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exoelectrogenic bacteria. For yield coefficient estimation, we modified McCarty’s free energy-

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based model by using the bioanode potential for the free energy of the electron acceptor reaction.

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The estimated true yield coefficient ranged 0.1 to 0.3 g-VSS (volatile suspended solids) g-COD-1

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(chemical oxygen demand), which is similar to that of most anaerobic microorganisms. The yield

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coefficient was sensitively affected by the bioanode potential and pH while the substrate and

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bicarbonate concentrations had relatively minor effects on the yield coefficient. In lab-scale

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experiments using microbial electrolysis cells, the observed yield coefficient (including the effect

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of cell decay) was found to be 0.020 ± 0.008 g-VSS g-COD-1, which is an order of magnitude

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smaller than the theoretical estimation. Based on the difference between the theoretical and

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experimental results, the decay coefficient was approximated to be 0.013 ± 0.002 d-1. These

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findings indicate that bioelectrochemical systems have potential for future wastewater treatment

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with reduced waste sludge as well as for resources recovery. Also, the found kinetic information

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will allow accurate estimation of wastewater treatment performance in bioelectrochemical

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systems.

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Keywords

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Wastewater sludge; microbial electrolysis cells; microbial fuel cells; microbial kinetics and

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energetics; yield coefficient; cell decay coefficient

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Nomenclature

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Abbreviations

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COD

chemical oxygen demand

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FID-GC

flame ionization detector-gas chromatography

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MDC

microbial desalination cell

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MEC

microbial electrolysis cell

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MFC

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RPM

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SHE

standard hydrogen electrode

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TSS

total suspended solids

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microbial fuel cell rotations per min

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VSS

volatile suspended solids

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Symbols

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A

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number of moles of electrons transferred to terminal electron acceptor out of A+1 moles (-)

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b

cell decay coefficient (d-1)

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c

sodium acetate concentration (mg L-1)

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CE

Coulombic efficiency (-)

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Ean

bioanode potential (V vs. SHE)

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F

Faraday constant (96485 C per mole-e−)

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m

exponent for electron transfer efficiency based on spontaneity of pyruvate creation (-)

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n

number of electrons transferred at the bioanode (-)

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V

volume of MEC chamber (L)

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Xanode

volatile biomass attached on the bioanode (g-VSS)

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Yobserved

observed yield coefficient (g-VSS g-COD-1)

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Ytrue

true yield coefficient (g-VSS g-COD-1)

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∆Ga

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∆Gc°ʹ

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free energy released from the electron acceptor reaction (kJ per mole-e−) free energy required to convert pyruvate to cellular carbon under standard conditions at pH 7 (kJ per mole-e−)

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∆Gd

free energy released from the electron donor reaction (kJ per mole-e−)

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∆Gn°ʹ

free energy required to create ammonia from other nitrogen sources under standard

∆Gp°ʹ

free energy required to convert the substrate to pyruvate under standard conditions at pH 7 (kJ per mole-e−)

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∆Gr

free energy that the microorganism obtains from the electron donor and acceptor reactions (kJ per mole-e−)

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∆Gs°ʹ

free energy required for cell synthesis under standard conditions at pH 7 (kJ per

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conditions at pH 7 (kJ per mole-e−)

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mole-e−)

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ε

electron transfer efficiency (-)

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τ

average time period of each fed-batch cycle (d)

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Superscripts

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an

anolyte or anode chamber

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cat

catholyte or cathode chamber

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Subscripts

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eff

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in

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effluent

influent

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1. Introduction Bioelectrochemical systems are an emerging method for wastewater treatment and

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simultaneous recovery of energy and valuable resources (Tice and Kim, 2014a; Zhang and

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Angelidaki 2015a; Zhang and Angelidaki 2015b; Kim et al., 2015; Qin et al., 2015). In

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bioelectrochemical systems, various reduction reactions at the cathode (e.g., hydrogen evolution,

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oxygen reduction, biofuel production, and heavy metal reduction) are coupled with oxidation of

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organic substrates at the bioanode (Logan et al., 2006; Logan et al., 2008; Modin et al., 2012;

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Nilges and Schröder, 2013). Exoelectrogenic bacteria, growing on bioanode surfaces, oxidize

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organic substrates and transfer electrons directly to the bioanode, creating electric current. The

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created electric current can be beneficially utilized in engineered bioelectrochemical systems.

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For instance, microbial fuel cells (MFCs) are used to generate electric power (Logan et al., 2006);

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microbial electrolysis cells (MECs) produce H2 gas (Logan et al., 2008); microbial desalination

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cells (MDCs) utilize the electric current to separate charged ions from salt water (Cao et al.,

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2009); and bioanodes can also be used as water quality sensors to monitor toxic contaminants

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(Ahn and Schröder, 2015). In addition to these beneficial aspects, bioelectrochemical systems

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were found in a recent study to produce substantially small amounts of waste sludge in

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wastewater treatment (Brown et al., 2015).

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In conventional activated sludge systems, approximately 60% of organic substrates are

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converted into heterotrophic cells on the COD (chemical oxygen demand) basis (Rittmann and

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McCarty, 2001; Grady et al., 2011). This high yield coefficient (0.6 g-COD g-COD-1) of

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heterotrophic bacteria results in substantial amounts of waste sludge in wastewater treatment.

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The waste sludge is further treated in anaerobic digesters and mechanical dewatering processes

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before sludge cakes are disposed of in landfills or burnt in incinerators. The sludge treatment and 5

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final disposal require high costs and especially the cost for the final disposal has dramatically

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increased as wet wastes (including wastewater sludge cakes) are regulated in landfill disposal. As

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a result, the cost for sludge treatment and disposal is one of the main expenses for wastewater

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treatment; thus, reduction in waste sludge will allow cost-effective wastewater treatment.

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In a recent study, bioelectrochemical systems were found to produce a substantially small amount of waste sludge (Brown et al., 2015); however, the yield coefficient of exoelectrogenic

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bacteria has not been quantified. Exoelectrogenic bacteria grow on anaerobic respiration as they

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originally use ferric iron or elemental sulfur as a terminal electron acceptor (Rotaru et al., 2011).

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Anaerobic microorganisms are known to have a relatively small yield coefficient (0.04 to 0.1 g-

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COD g-COD-1 at 35°C) compared to aerobic microorganisms (0.67 g-COD g-COD-1 for

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heterotrophs and 0.24 g-COD g-N-1 for autotrophs at 20°C) (Batstone et al., 2002; Henze, 2000).

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Thus, the exoelectrogenic yield is expected to be small within the typical range for anaerobic

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microorganisms. In addition, the energy level that is applied to exoelectrogenic bacteria can be

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easily regulated by controlling the bioanode potential during bioelectrochemical system

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operation. For instance, when a new bioelectrochemical system is started, the yield coefficient

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will be maximized for a rapid start-up of the system. However, when exoelectrogenic biofilms

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are fully developed on the bioanode, the yield coefficient will be minimized to reduce the

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production of waste sludge.

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The rate of cell decay in biological wastewater treatment also affects the amount of waste

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sludge production. The rate of cell decay is known to be linearly proportional to the microbial

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population in bioreactors (Rittmann and McCarty, 2001; Grady et al., 2011). Thus, attached

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growth bioreactors (e.g., trickling filters, rotating biological contactors, moving bed biofilm

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reactors) generate small amounts of waste sludge compared to suspended growth bioreactors 6

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(e.g., activated sludge) because relatively dense microbial populations in biofilms (>10,000 mg-

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volatile biomass L-1) induce high rates of cell decay (Grady et al., 2011). Note that the microbial

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population in suspended growth bioreactors is usually an order smaller, ranging 1,000 to 4,000

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mg-VSS (volatile suspended solid) L-1. Since exoelectrogenic bacteria form biofilms on the

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bioanode, the rate of cell decay is expected to be high and thus bioelectrochemical systems are

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expected to generate a small amount of waste sludge. However, none of previous studies have

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reported kinetic information on cell decay of exoelectrogenic bacteria in bioelectrochemical

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systems.

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One of the main objectives of this study is to demonstrate a theoretical method to estimate the yield coefficient of exoelectrogenic bacteria in bioelectrochemical systems by

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modifying McCarty’s free energy-based method (Rittmann and McCarty, 2001). By using the

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developed method, various operational factors (i.e., bioanode potential, pH, substrate

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concentration, and bicarbonate concentration) were examined to explain how they affect the rate

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of exoelectrogenic growth. Another important objective of this study is to determine the

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observed yield coefficient of the bioanode in a lab-scale experiment. By comparing the observed

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yield coefficient from the experiment with the theoretical true yield coefficient, the cell decay

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coefficient was approximated to quantify the contribution of cell decay to overall sludge

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production in bioelectrochemical systems.

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2. Microbial energetics for cell yield estimation

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2.1 Energy from electron donor and acceptor reactions (∆Gr)

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In bioelectrochemical systems, exoelectrogenic bacteria on the bioanode obtain energy from oxidation of organic substrates (i.e., electron donor reaction) and transfer of electrons to the

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bioanode (i.e., electron acceptor reaction) (Rittmann and McCarty, 2001).

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∆Gr = ε(∆Gd – ∆Ga)

(1)

∆Gr is the free energy that bacteria obtain from the electron-donor and -acceptor reactions per

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mole of electron transfer. The electron transfer efficiency (ε) was assumed to be 0.6 in this study

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(Rittmann and McCarty, 2001) unless otherwise noted. With acetate as an organic substrate, the

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free energy of the donor reaction (∆Gd) can be found based on the acetate oxidation half reaction

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(Rittmann and McCarty, 2001):

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HCO  






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∆ = ∆ ° + 

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+ H + e ↔ CH COO +  H O {CH3 COO− }/

(2)

(3)

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{ !"#$ }/%

∆Gd°ʹ = 26.87 kJ/mole-e−

In bioelectrochemical systems, the electron acceptor reaction occurs at the bioanode as

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exoelectrogens directly transfer electrons to electrically conductive bioanode surfaces. Thus, the

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free energy of the electron acceptor reaction (∆Ga) is determined by the bioanode potential as: ∆Ga = −nFEan

(4)

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F is the Faraday constant (96485 C per mole-e−), Ean is the bioanode potential in volts, and n is

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the number of electrons transferred by exoelectrogens in the bioanode reaction. In this study, n

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was assumed to be unity since most enzymes in bacterial electron transfer chains carry a single

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charge (Madigan et al., 2005). For instance, the cytochrome c enzyme is known to play a key

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role in the exoelectrogenic capability of Geobacter and Shewanella species in bioelectrochemical

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systems (Richter et al., 2012; Malvankar et al., 2012) and the enzyme carries a single electron

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depending on the oxidation state of its central metal (Madigan et al., 2015).

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2.2 Energy required for cell synthesis (∆Gs)

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In microbial energetics, new cells are synthesized in two steps: from a carbon source to pyruvate; and from pyruvate to the cellular carbon (Rittmann and McCarty, 2001). Also, a

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certain amount of energy (∆Gn°ʹ) is required to create ammonia (i.e., readily available nitrogen

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source) from other nitrogen sources (e.g., nitrate, nitrogen gas). Thus, the free energy required

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for cell synthesis (∆Gs°ʹ) can be written as: ∆& ° =

∆'( °) *+

+

∆', °) *

+ ∆- °

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(5)

∆Gp°ʹ is the free energy to covert a given carbon source to pyruvate under standard conditions at

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pH 7 (∆Gp°ʹ = 7.57 kJ per mole-e− for acetate as the carbon source, Rittmann and McCarty,

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2001). If the carbon source-to-pyruvate reaction is thermodynamically spontaneous, the exponent

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m is −1 while it is +1 if the reaction is non-spontaneous (Rittmann and McCarty, 2001). ∆Gc°ʹ is

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the free energy required to convert pyruvate into new microbial cells under standard states at pH

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7 (∆Gc°ʹ = 18.81 kJ per mole-e−, Rittmann and McCarty, 2001). Since a sufficient amount of

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ammonia was provided in the feed solution, ∆Gn°ʹ was assumed to be zero in this study.

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2.3 Energy balance to determine yield coefficient

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In McCarty’s microbial energetics model, if (A+1) moles of electrons are released in the

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electron donor reaction, one mole of electrons are used for cell synthesis and A moles of

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electrons are transferred to the terminal electron acceptor though the electron acceptor reaction

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(Rittmann and McCarty, 2001). The total amount of energy released from the electron donor

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reaction is also split by the same ratio. At steady state, the energy from the electron-donor and -

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acceptor reactions (Aε∆Gr) is identical to that required for cell synthesis (∆Gs°ʹ). Thus, the

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fraction constant A can be found as:

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.=−

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∆'/ °)

(6)

∆'0

By finding the fraction of the electron flow to cell synthesis (1/(A+1)), the true (theoretical) yield

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coefficient was further calculated using C5H7O2N for the chemical formula of new cells

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(Rittmann and McCarty, 2001).

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3. Experimental Method

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3.1 MEC construction

In lab-scale experiments, the microbial electrolysis cell (MEC) was constructed using

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polypropylene blocks with a cylindrical interior chamber (3.81 cm in diameter). The reactor

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consisted of an anode and a cathode chambers (70 and 30 mL, respectively) which were

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separated by a cation exchange membrane (Selemion CMV, Asahi Glass, Japan). Note that the

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separation was necessary so that the biomass produced in the anode chamber was not affected by

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potential microbial activities in the cathode chamber by hydrogenotrophic methanogens (Tice

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and Kim, 2014b) and sulfate reducing bacteria (Rabaey et al., 2005). A graphite fiber brush was

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used as the bioanode which was pretreated in a muffle furnace at 505°C for 2 hours (Wang et al.,

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2009). The cathode was a piece of stainless steel mesh without any catalyst applications (200 ×

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200 mesh; Type 304; McMaster Carr, USA). A gas collection tube was attached on top of the

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cathode chamber using epoxy glue. The constructed MEC was inoculated using primary effluent

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from a local wastewater treatment facility and operated about 6 weeks before the main part of the

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experiment was initiated.

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3.2 Feed solution preparation

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The feed solution was prepared with 60 mM phosphate buffer solution (10.38 g L-1

Na2HPO4-7H2O; 2.55 g L-1 NaH2PO4; 0.36 g L-1 NH4Cl; 0.15 g L-1 KCl). Approximately 0.02

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mM NaOH was added into the phosphate buffer solution and the resulting pH ranged 9.0 to 9.5.

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This high pH condition was necessary to avoid potential acidification in the anode chamber that

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can limit the exoelectrogenic growth and activity on the bioanode (He et al., 2008). The prepared

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solution was directly used as the catholyte solution while the anolyte solution was then further

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prepared through the addition of 1 g L-1 sodium acetate as well as trace vitamins and minerals

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(Cheng et al., 2009).

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3.3 Reactor operation

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Three independent MECs were operated in a fed-batch mode and each fed-batch cycle lasted between 3 and 5 days (2 cycles per week). The MECs were operated at an applied voltage

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(Eap) of 1.0 V for the bioanode yield and Coulombic efficiency measurement while three

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different applied voltages (1.0, 0.75, and 0.5 V) were examined when the anode potential was

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monitored using an Ag/AgCl reference electrode (MW-2030; BASi, USA). The voltage

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application, bioanode potential monitoring, and current measurement were conducted using

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multi-channel potentiostat (MPG2, Bio-Logic Science Instruments; France). All experiments

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were performed in an air conditioned laboratory with a stationary temperature of 21.2 ± 0.8°C.

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3.4 Experimental measurements

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For the solid analysis, 60 mL was taken from the anolyte effluent (70 mL) and acidified using HCl before it was divided into two 30 mL samples which were individually centrifuged at

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9000 RPM (rotations per min) for 20 min to separate suspended biomass. Approximately 22.5

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mL of the supernatant was poured off without disturbing the centrifuged biomass adhered to the

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wall of the centrifuge tube. The remaining sample was sonicated briefly to dislodge the biomass

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and then poured into a ceramic crucible. The crucible was kept in a 103°C oven for at least 12 hr

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and heated to 505°C for 2 hr in a muffle furnace to determine volatile and total suspended solids

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(VSS and TSS). Note that a small amount of dissolved solids in the remaining sample (7.5 mL)

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was included in the measurement of VSS and TSS. It should be emphasized that the standard

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methods for VSS and TSS using filter disks (Eaton et al., 2005) was not sensitive enough to

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detect the biomass production in the MECs since the observed yield of the bioanode was

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extremely small (~0.02 g-VSS g-COD-1).

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The influent and effluent solutions were analyzed for pH and conductivity (SevenMulti;

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Mettler-Toledo International Inc., USA). The anolyte pH decreased from 9.2 to 6.3 while the

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catholyte pH increased from 9.3 to 12.1 since the anode and cathode chambers were separated by

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a cation exchange membrane. The anolyte conductivity decreased from ~10.43 to 6.96 mS cm-1

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while the catholyte conductivity increased from ~10.04 to 19.21 mS cm-1 because the anode

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chamber loses cations through the cation exchange membrane (Strathmann, 2004).

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After 99 days of the MEC operation, the reactors were dissembled and the carbon fiber

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brush bioanodes were dried at 105° and burnt at 505°C to determine the amount of volatile

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biomass growing on the bioanode.

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3.5 COD removal and Coulombic efficiency

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In a separate experiment, the effluent anolyte and catholyte as well as the influent anolyte

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were taken and acidified using phosphoric acid (3% v/v). The acidified samples were analyzed in

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FID-GC (flame ionization detector-gas chromatography) to determine acetate concentration

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(Varian CP3800, USA). In the FID-GC analysis, the Stabilwax-DA column was used to separate

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individual organic fatty acids (Restek, USA). It should be noted that acetate was detected in the

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effluent catholyte at low concentration (16.1 ± 7.9 mg L-1 as sodium acetate; n = 6) due to non-

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ideality of the cation exchange membrane. The chemical oxygen demand removal (∆COD) was

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determined by performing the mass balance on sodium acetate:

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88=8> ∆COD = 0.78(7 8- 9:− 7 8- 9;<< − 7 =8> 9;<< )

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(7)

The factor 0.78 is for the conversion from mg-sodium acetate into mg-COD, c is the sodium

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acetate concentration measured in the FID-GC analysis, V is the volume with the superscript an

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for anolyte and cat for catholyte. The subscript in is for influent and eff for effluent.

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The Coulombic efficiency (CE) is the charge-based ratio between the amount of electric current (i) generated and the amount of COD removed during MEC fed-batch cycles: @A =

C :> D∆!"E

(8)

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The measured CE was 107.9 ± 5.1% (n = 6) and this high CE result indicates that the majority of

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provided acetate was oxidized by the bioanode. Thus, the biomass produced in the anode

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chamber was mainly contributed by the excess growth of exoelectrogenic bacteria on the

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bioanode. After confirming consistently high CE, COD was not further monitored in the

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bioanode yield experiment and ∆COD was determined by integrating electric current with time

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by assuming CE of 100%.

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3.6 Decay coefficient estimation The cell decay coefficient (b) was calculated by comparing the true yield coefficient (Ytrue) and observed yield coefficient from the experiment (Yobserved). F=

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(GH0IJ GKL/J0MJN )O PQ ∆!"E

(9)

RPQKNJ S

Xanode is the volatile biomass attached on the bioanode and τ is the average time period of the fed-

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batch cycle.

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4. Results and Discussion

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4.1 Anode potential and pH governing bioanode cell yield

The anode potential was found to govern the excess cell yield on the bioanode. The yield

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coefficient sharply increased with increasing anode potential from −0.4 to 0 V vs. SHE (standard

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hydrogen electrode) (Fig 1A). A more positive anode potential corresponds to a greater amount

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of energy available for bacterial growth. The equilibrium anode potential of the bioanode is

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−0.293 V vs. SHE (10 mM acetate; 10 mM bicarbonate; pH = 7; 25°C) using the Nernst equation

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(Logan et al., 2008). This equilibrium anode potential corresponds to a zero cell yield of

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exoelectrogenic bacteria (i.e., x-intercept of the pH 7 curve in Fig 1A), indicating that the

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developed method for the yield coefficient is consistent with the prediction based on

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electrochemistry equilibrium. Based on the slope of the yield vs. anode potential curve, there is

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an increase of approximately 0.1 g-VSS g-COD-1 in the yield coefficient per 0.1 V increase in

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the anode potential. The anode potential in MFCs and MECs can be wide but usually in the range

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of –0.1 to –0.3 V vs. SHE (Aelterman et al., 2008; Torres et al., 2009; Wagner et al., 2010; Lee

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and Rittmann, 2010; Nam et al., 2011; Sun et al., 2012). Assuming the anode potential of –0.1 V

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vs. SHE under neutral to slightly basic conditions (pH 7 to 9), the theoretical yield coefficient of

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exoelectrogenic bacteria will range 0.1 to 0.2 g-VSS g-COD-1.

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A change in pH also resulted in a sensitive response in the yield coefficient as an increase in pH by two units raised the yield coefficient by ~0.1 g-VSS g-COD-1 (Fig 1A). It should be

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emphasized that very small cell yield coefficients were observed at pH 5 (e.g., 0.05 g-VSS g-

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COD-1 at −0.1 V vs. SHE). This observation indicates that the exoelectrogenic growth is

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seriously inhibited even at the mildly acidic pH condition. This finding is consistent with

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experimental results reported in the previous studies that the bioanode practically stops

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generating electric current at pH of 5 or lower (He et al., 2008).

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Exoelectrogenic bacteria form biofilms on bioanode surfaces, and thus the local pH and electric potential vary in the exoelectrogenic biofilm. For instance, the local pH is lower and the

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electric potential is more positive at a deeper location of the biofilm (Babauta et al., 2012),

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leading to a decrease and an increase in the microbial yield, respectively (Fig 1A). In addition,

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such variations in the local pH and electric potential are more pronounced at higher current

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conditions (Babauta et al., 2012). Thus, the yield coefficient can be slightly different at different

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locations in exoelectrogenic biofilms. While the scope of this study does not include such micro-

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scale environmental factors on the yield coefficient, this interesting aspect can be further

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investigated in future studies.

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4.2 Substrate and bicarbonate concentration

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The substrate (acetate) concentration has relatively minor effects on the biomass production. The yield coefficient increased gradually (~10% of its magnitude) with the

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increasing substrate concentration up to 20 mM acetate or 1.28 g-COD/L (Fig 1B) because high

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substrate concentration decreases the amount of energy required for new cell synthesis, leaving a

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greater amount of energy for cell growth. Conversely, an increase in bicarbonate concentration

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increases the energy required for cell synthesis, resulting in a smaller yield coefficient. However,

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the result shows that both acetate and bicarbonate concentrations have relatively minor effects on

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the bioanode yield coefficient. Note that there was only ~10% decrease in the yield coefficient

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with an increase in bicarbonate concentration by an order of magnitude (Fig 1B).

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4.3 Sensitivity analysis on electron transfer efficiency

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While the electron transfer efficiency (ε) is commonly assumed to be 0.6, its precise estimation is difficult without a clear understanding of proton motive force generation in the

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electron transport chain (McCarty, 2007). Thus, we examined the sensitivity of the yield

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coefficient to the electron transfer efficiency. As the electron transfer efficiency increased, the

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microbial yield coefficient increased (Fig 1C) because the bacteria obtain a greater amount of

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energy from substrate utilization (∆Gr in Eq. 1) while they need a smaller amount of energy for

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cell synthesis (∆Gs°ʹ in Eq. 5) with a higher electron transfer efficiency. Note that ∆Gp°ʹ was

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always positive unless bicarbonate concentration is extremely low (e.g., [HCO3-] ≤ 0.001 mM),

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indicating that the reaction from acetate to pyruvate is usually non-spontaneous. When the

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bioanode potential was more positive, the sensitivity of the yield coefficient to the electron

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transfer efficiency was more pronounced (Fig 1C). This observation can be explained by more

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negative free energy for the electron acceptor reaction (∆Ga in Eq. 4) when the bioanode

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potential is more positive, leading to a greater amount of energy available for microbial growth.

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4.4 Observed yield coefficient in experiments

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The observed yield coefficient obtained from the MEC experiment was substantially small at about 0.020 g-VSS g-COD-1 (Table 1). In the experiment, the anolyte pH ranged from

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9.2 to 6.3 and the anode potential was stable about −0.1 V vs. SHE for Eap of 1.0 V when the

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bioanode is active in generating electric current with acetate (Fig 2). For these given conditions,

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the true yield coefficient of the bioanode is expected to decrease from 0.2 to 0.1 g-VSS g-COD-1

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with the decreasing pH from 9.2 to 6.3 (Fig 1A). When compared with this theoretical

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estimation, the observed yield coefficient is smaller by an order of magnitude. For the

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consecutive 6 fed-batch cycles, the electric current was high with the peak current ranging 0.6 to

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3.2 mA (Fig 3), indicating that the bioanode was healthy and thus actively oxidizing the organic

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substrate (acetate) over the course of the experiments. Thus, the substantially small observed

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yield coefficient was not contributed by any potential malfunctions of the bioanode during the

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experiment.

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Since the MEC reactors were operated at a fed-batch mode, acetate concentration

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decreased with time and thus low acetate concentration near the end of fed-batch cycles could

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potentially have resulted in the small observed yield coefficient. However, for the 5th and 6th

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fed-batch cycles, the electric current was high about 1 mA or higher when the fed-batch

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operation was terminated at 18 and 21 d, respectively (Fig 3). This high current indicates that

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acetate concentration was sufficiently high at the end of these two fed-batch cycles so that the

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bioanode actively oxidized acetate and thus created the high electric current throughout the fed-

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batch cycles. The observed yield coefficient for the 5th and 6th cycles was 0.032 and 0.016 g-

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VSS g-COD-1, respectively while the average observed yield coefficient over 6 fed-batch cycles

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was 0.020 g-VSS g-COD-1 (Table 1). Thus, potentially low substrate concentration near the end

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of fed-batch cycles cannot explain the substantial difference between the observed and

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theoretical yield coefficients.

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4.5 Cell decay on bioanodes

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The cell decay at the bioanode can explain the substantial difference between the

observed yield coefficient in the experiment (0.020 g-VSS g-COD-1) and the theoretical true

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yield coefficient (0.1 to 0.2 g-VSS g-COD-1). At the end of the 3-month MEC operation, the

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amount of volatile biomass on the bioanode was measured to be 126.7 ± 8.7 mg VSS per

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bioanode. Based on this biomass measurement, the decay coefficient was plotted using Eq. 9 as a

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function of true yield coefficient (Fig 4). The decay coefficient was zero when the true yield

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coefficient is equal to the observed yield coefficient (0.020 g-VSS g-COD-1) and it increased

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linearly with the increasing true yield coefficient (Fig 4). During the MEC operation, the anode

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potential was −0.1 V vs. SHE (Fig 2) and the average pH in the anode chamber was

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approximately 8. Thus, the resulting true yield coefficient (Ytrue) was 0.2 g-VSS g-COD-1 (Fig

377

1A) and consequently the decay coefficient can be estimated to be 0.013 ± 0.002 d-1 (Fig 4). This

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estimated decay coefficient is similar to the suggested value for anaerobic microorganisms in

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Anaerobic Digestion Model No. 1 (0.02 d-1 at 35°C) (Batstone et al., 2012). Thus, the rate of cell

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decay in bioelectrochemical systems is comparable to that in anaerobic digestion.

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Using the estimated decay coefficient (0.013 d-1), the amount of exoelectrogenic cells

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decayed was found to be 5.78 mg VSS per fed-batch cycle (0.013 d-1 × 126.7 mg VSS × 3.5 d).

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The created volatile biomass using the true yield coefficient was 6.42 mg VSS per cycle (0.2 mg-

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VSS mg-COD-1 × 458.4 mg-COD L-1 × 0.070 L). Thus, the amount of exoelectrogenic cells

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decayed was approximately 90% of the amount of newly created cells on the bioanode. This

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comparison explains the substantially reduced waste sludge production in bioelectrochemical

387

wastewater treatment that was demonstrated in a recent study (Brown et al., 2015).

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5. Conclusions

In this study, we estimated the true (theoretical) cell yield coefficient of exoelectrogenic

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bacteria in bioelectrochemical systems by modifying McCarty’s free energy-based method. The

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theoretical yield coefficient ranged 0.1 to 0.3 g-VSS g-COD-1 (pH 7 – 9; anode potential between

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−0.2 and 0 V vs. SHE; ε = 0.6), which is similar to that of most anaerobic microorganisms

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growing in anaerobic digesters (Batstone et al., 2012) but much smaller than that of aerobic

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microorganisms in activated sludge systems (Henze, 2000). The true yield coefficient of

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exoelectrogenic bacteria was greatly affected by pH and as a result, even a mildly acidic

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condition (e.g., pH 5) seriously inhibited the bacterial growth on bioanodes. This finding is

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consistent with previous study results where the bioanode practically stops creating electric

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current at pH 5 or lower (He et al., 2008). The exoelectrogenic yield was also governed by the

400

anode potential as the true yield coefficient increased with the increasing (i.e., more positive)

401

anode potential. However, the reactant (substrate) and product (bicarbonate) concentration had

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relatively minor effects on the yield coefficient of exoelectrogenic bacteria. While the electron

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transfer efficiency is commonly assumed to be 0.6, the sensitivity study result found that the

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estimation of the yield coefficient is greatly affected by the electron transfer efficiency. This

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finding indicates that precise estimation of the electron transfer efficiency is necessary in future

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studies when the electron transfer chain in exoelectrogenic cells are clearly understood.

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In the experiment using lab-scale MECs, the observed yield coefficient was found to be 0.020 ± 0.008 g-VSS g-COD-1, which is smaller than the true yield coefficient by an order

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magnitude. After the 3-month experiment was completed, the total amount of biomass on the

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bioanode was measured and 126.7 ± 8.7 mg volatile solids were found to be attached on each

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bioanode. Based on this measurement, the rate of cell decay was obtained from the difference

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between the true and observed yield coefficients. The estimated decay coefficient was 0.013 ±

413

0.002 d-1 at 21.2°C, which is similar to that of anaerobic microorganisms in anaerobic digesters

414

(0.02 d-1 at 35°C) ( Batstone et al., 2012). Using the obtained decay coefficient, the amount of

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cell decayed over the fed-batch cycle was 5.78 mg VSS, which was 90% of the created cell (6.42

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mg VSS), explaining the substantially small observed yield coefficient.

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The found yield and decay coefficients will be used in model developments and

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simulations of bioelectrochemical systems to predict their performance of wastewater treatment

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and resources recovery. The substantially small observed yield coefficient of exoelectrogenic

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bacteria (0.020 g-VSS g-COD-1) confirmed a strong potential of bioelectrochemical systems for

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future wastewater treatment with greatly reduced sludge generation as recently demonstrated

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(Brown et al., 2015). Considering that sludge treatment and disposal are responsible for major

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expenses in wastewater treatment, bioelectrochemical systems can effectively reduce the cost for

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wastewater treatment.

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Acknowledgements

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This study was supported by Discovery Grants (435547-2013, Natural Sciences and Engineering

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Research Council of Canada), Canada Research Chairs Program (950-2320518, Government of

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Canada), Leaders Opportunity Fund (31604, Canada Foundation for Innovation), Ontario

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Research Fund-Research Infrastructure (31604, Ontario Ministry of Economic Development and

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Innovation), and Undergraduate Student Research Awards (Natural Sciences and Engineering

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Research Council of Canada). The authors thank Ms. Anna Robertson and Mr. Peter Koudys for

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their help on equipment operation and reactor construction.

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Tables

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Table 1. Summary of experimental results to find the observed yield coefficient.

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Fed-batch cycle 1 2 3 4 5 6 Mean ± SD -1 VSS (mg L ) 6.59 10.86 5.84 9.16 13.22 8.41 9.01 ± 2.73 ∫idt (C) 401.1 447.2 381.9 307.6 345.1 439.3 387.0 ± 54.1 ∆COD (mg L-1)* 475.1 529.7 452.4 364.4 408.7 520.4 458.4 ± 64.1 Observed yield 0.0139 0.0205 0.0129 0.0251 0.0323 0.0162 0.0202 ± 0.0075 (g-VSS g-COD-1) * Coulombic efficiency of 100% was assumed as demonstrated in a separate experiment.

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0.1

0.2

0.1

0.0

0.0

(C)

−0.1 V vs. SHE −0.2 V vs. SHE −0.3 V vs. SHE

0.2

0.1

0.0

0

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10 15 Acetate (mM)

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0.1 mM HCO₃ˉ 1.0 mM HCO₃ˉ 10.0 mM HCO₃ˉ

(B)

Yield (g‐VSS/g‐COD)

0.3

(A)

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pH = 9 pH = 7 pH = 5

Yield (g‐VSS/g‐COD)

Yield (g‐VSS/g‐COD)

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0

0.2 0.4 0.6 Transfer efficiency

0.8

Figure 1. The true yield coefficient estimation. (A) Effect of anode potential and pH (10 mM acetate; 10 mM bicarbonate; ε = 0.6; 25°C) (B) Effect of acetate and bicarbonate concentration (pH = 7; anode potential = −0.1 V vs. SHE; ε = 0.6; 25°C) (C) Sensitivity

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bicarbonate; 25°C).

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-0.1

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MEC-1 MEC-2 MEC-3

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-0.4 0.25

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Anode potential (V vs SHE)

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Figure 2. Relationship between the applied voltage (Eap) and anode potential (Ean).

MEC-1 MEC-2 MEC-3

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Electric current (mA)

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Figure 3. Electric current during the apparent yield coefficient measurement over 6 fed-batch

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ΔCOD = 458 mg/L ΔCOD = 394 mg/L

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ΔCOD = 523 mg/L

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Decay coefficient (d-1)

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0.1 0.2 0.3 True yield coefficient (g-VSS/g-COD)

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Figure 4. Decay coefficient estimation using Eq. 9. (ΔCOD = 458.4 ± 64.1 mg-COD L-1 (Table 1); Apparent yield coefficient = 0.02 g-VSS g-COD-1; anolyte volume = 70 mL; average

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Highlights The true yield coefficient of exoelectrogenic bacteria was 0.1 to 0.3 g-VSS g-COD-1. More positive anode potential and higher pH resulted in greater cell yield.

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The apparent yield coefficient of exoelectrogens was 0.020 ± 0.008 g-VSS g-COD-1. The decay coefficient of exoelectrogens was estimated to be 0.013 ± 0.002 d-1.

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Waste sludge production in bioelectrochemical systems was substantially small.