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Enzymatic electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system
Accepted Manuscript Enzymatic electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system
Lijuan Zhang, Jacky Ong, Junyi Liu, Sam Fong Yau Li PII:
S0960-1481(17)30190-8
DOI:
10.1016/j.renene.2017.03.009
Reference:
RENE 8602
To appear in:
Enzymatic electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system
Received Date:
20 June 2016
Revised Date:
15 February 2017
Accepted Date:
02 March 2017
Please cite this article as: Lijuan Zhang, Jacky Ong, Junyi Liu, Sam Fong Yau Li, Enzymatic electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system, Enzymatic
electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system (2017), doi: 10.1016 /j.renene.2017.03.009
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Highlights
A MFC-EFC system was developed for bioelectrochemical CO2-to-formate conversion.
Electrocatalytic CO2 reduction was achieved with lowered overpotential by CbFDH.
Formate was bioelectro-synthesized from specific and sustainable CO2 reduction.
The hybrid system could be driven by bioelectric power from wastewater.
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Enzymatic electrosynthesis of formate from CO2 reduction in a
2
hybrid biofuel cell system
3
Lijuan Zhang a, Jacky Ong a, Junyi Liu a, Sam Fong Yau Li a,b*
4
a Department
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117543, Singapore
6
b
7
117411, Singapore
of Chemistry, Faculty of Science, National University of Singapore, Singapore
NUS Environmental Research Institute, National University of Singapore, Singapore
8 9 10
*
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Tel.: +65 65162681; fax: +65 67791691.
12
E-mail address: [email protected] (S.F.Y. Li).
Corresponding author.
1
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Abstract
15
To seek a sustainable way of CO2 sequestration and conversion, enzymatic electrosynthesis
16
(EES) of formate from CO2 reduction has been investigated in a hybrid biofuel cell system.
17
In an enzymatic fuel cell (EFC), waste CO2 species are specifically reduced to energy-rich
18
product of formate under mild biological conditions. Efficient formate production can be
19
achieved at lowered electrode potential owing to the electrochemically active participation
20
of formate dehydrogenase (CbFDH) as a biocatalyst. Electropolymerized neutral red
21
(PolyNR) is proven to be a promising modifier to enhance the electrochemical behavior of
22
enzymatic electrode, as well as a reducing reagent to regenerate mediator of NADH in
23
enzymatic CO2 reduction. Electrons for EES are extracted from the organic pollutants in
24
wastewater by microbial fuel cell (MFC) stacks arranged in series and/or parallel with
25
different unit numbers (n = 1, 2 and 3). The maximum formate production rate reaches around
26
60 mg L-1 h-1 with a Faraday efficiency of 70% in the EFC powered by a three-MFC stacked
27
in series. In view of practical applications, the hybrid MFC-EFC system has been
28
demonstrated to be advantageous in both product specificity and energy sustainability.
29
30 31
Keywords: Enzymatic fuel cell, Microbial fuel cell, CO2 reduction, Formate synthesis,
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Formate dehydrogenase 2
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1. Introduction
34
With a rapid expansion of industrialization, anthropogenic carbon dioxide (CO2) that is
35
excessively emitted to atmosphere becomes an important greenhouse gas (GHG) in climate
36
change. GHG mitigation has been made a long-term commitment by many countries [1]. CO2
37
accounts for two thirds of the total GHG emitted by human activities, and is reported to be
38
the primary contributor to global warming. In the last century, global anthropogenic carbon
39
emission from fossil fuels has increased by around 10 times [2]. Among many industrial
40
emission sources, CO2 discharged from traditional wastewater treatment processes is of
41
particular interest to many environmental researchers. Tremendous amount of CO2, i.e. an
42
estimated 1.21 × 104 tons per day by 2025 [3], are released from the degradation of organic
43
pollutants in wastewater treatment plants worldwide. Although it is a causal factor in
44
warming the atmosphere and a waste product in treating wastewater, the inorganic CO2 can
45
be utilized as a substrate carbon source for synthesis of organic carbonates (e.g. formic acid,
46
acetate and methanol) [4, 5]. Thus far, efficient CO2 capture, sequestration and utilization
47
(CCSU) in wastewater treatment facilities is crucial to mitigate the potential impacts of CO2
48
on climate change and environment pollution.
49
To make the CCSU cycle virtuous, conversion of pollutants → CO2 → biofuels is a
50
desirable pathway to secure the molecular values of carbonaceous substrates in wastewater.
51
CO2 reduction to formate (or formic acid), which is the first step in methanol or methane
52
production route, is of particular interest in practical biofuel and bioenergy engineering.
53
Various CO2-to-formate conversion technologies have been well developed but are
54
challenged by different problems, such as the high energy consumption in electrochemical
55
reduction [6, 7] and the low reaction efficiency in bioconversion [8]. Recent studies illustrate
56
that efficient and specific synthesis of formate from CO2 reduction can be achieved by some 3
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biocatalysts in a bioelectrochemical system [9, 10]. Several whole microbial cells have
58
shown the ability to reduce CO2 to formate by decreasing the overpotential at electrodes.
59
However, the reaction rates were very low in most situations (experimental periods up to
60
days) [11]. Rapid and oriented electron movement from CO2 to formate has been proven to
61
be feasible by particular isolated enzymes such as formate dehydrogenase (FDH) in an
62
enzymatic fuel cell (EFC) [12, 13]. On the anode of an EFC, water or organic molecules are
63
oxidized, releasing protons and electrons. The electrons are transported from anode to
64
cathode where enzymatic electrosynthesis (EES) of formate takes place. On the cathode of
65
an EFC, the electrons are suggested to be transferred from solid electrode toward dissolved
66
CO2 species via the active sites of FDH, overcoming the high overpotential to activate CO2
67
reduction [14, 15]. Therefore, the energy input to an EFC can be decreased considerably
68
owing to the catalysis by FDH. Current FDH-reducing CO2 technology, however, suffers
69
from huge gaps in practical application. There are few well-applied systems in aqueous
70
conditions, especially in wastewater medium. And the limited studies on FDH reported only
71
partial CO2 reduction within deficient lifetime of enzyme. Moreover, there is a requirement
72
for electromotive force to drive EES for higher yield of formate. A driving force can be
73
expected from an external power supply such as a commonly used potentiostat [13, 16]. With
74
a growing demand for energy worldwide, however, a renewable electricity source is urgently
75
needed to be explored.
76
Microbial fuel cell (MFC) has been investigated to generate electricity by
77
electrochemically active bacteria (EAB) for more than a decade [17]. It has been extensively
78
considered as a promising source of power alternative to extract electrons from wastewater,
79
in which process the organic pollutants can be removed to produce clean water
80
simultaneously [18-20]. Nevertheless, as compared with the release of electrons, little
81
attention has been paid to the production of inorganic carbonaceous substrates such as 4
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carbonate/bicarbonate from organic pollutants degradation in which process CO2 might be
83
emitted to the atmosphere. Even less effort has been made to convert the produced CO2
84
wastes to valuable chemicals [21].
85
In this study, we aimed at enzymatic electrosynthesis of formate from CO2 reduction in a
86
hybrid MFC-EFC system. The electrons, i.e. CO2-reducing agents, were extracted from the
87
degradation of organic pollutants in wastewater by EAB in MFCs. A highly efficient and
88
reusable enzymatic cathode was fabricated for EES of formate in an EFC. FDH from
89
Candida boidinii (CbFDH) was immobilized on to surface of enzymatic cathode as
90
biocatalysts, and neutral red was deposited by electro-polymerization to enhance the
91
electrochemical properties of cathode. Specific and sustainable production of formate was
92
inspected at lowered electrode potentials in the EFC by implementing metallurgical MFC
93
stack in series or parallel connection as an external power supply.
94
2. Materials and methods
95
2.1 Hybrid MFC-EFC system
96
The hybrid biofuel cell system was constructed with an EFC and several series/parallel-
97
stacked metallurgical MFCs (unit number n = 1, 2 and 3 as shown in Fig. 1). Both EFC and
98
MFC were dual-chamber reactors separated by proton exchange membrane (PEM). The
99
chambers were sealed with silica gel to prevent any potential permeation of atmospheric CO2
100
and/or O2. All electrodes were carbon-based materials (Beijing Sanye Carbon Co., Ltd.,
101
China). They were firstly soaked in acetone overnight, thence in acid mixture of
102
H2SO4:HNO3 (1:3) for 6.0 h, and further cleaned in 0.20 M H2SO4 solution by cyclic
103
voltammetry (CV) between -0.50 V and +1.50 at 50 mV/s for 3 cycles. These clean electrodes
104
were subsequently annealed at 370 ℃ for 0.5 h, and equilibrated in 100 mM phosphate
5
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buffered saline (PBS, 11,472 mg L-1 Na2HPO4·2H2O and 4,904 mg L-1 NaH2PO4·H2O) prior
106
to use. The whole circuit was connected via pure titanium wires (> 99.9%).
107
The EFC reactor consisted of a cathodic and an anodic working volume of 20 mL each.
108
The anode was a single piece of highly porous graphite felt (2.5 cm length × 2.5 cm width ×
109
1.0 cm thickness). The enzymatic cathode was based on a simple graphite rod (GR, 1.5 mm
110
in diameter × 2.5 cm in length, Beijng Sanye Carbon Co., Ltd., China). Polymerized neutral
111
red (PolyNR) was electro-deposited onto the GR electrode in 100 mM PBS (pH 6.0) with
112
0.40 mM neutral red. CV was carried out between -0.80 V and +0.80 V at 50 mV/s for 100
113
cycles [22]. Enzyme (1.0 unit) was immobilized onto the surface of PolyNR-GR electrode
114
by modified Nafion micelles. The Nafion micelles (~5% in a mixture of lower aliphatic
115
alcohols and water) were pretreated with tetrabutyl ammonium bromide as reported
116
previously [23]. The fabricated enzymatic electrode was allowed to air dry at 4 ℃ for 4.0 h
117
and equilibrated in 100 mM PBS for at least 0.50 h before use.
118
The metallurgical MFC comprised an anodic working volume of 200 mL and a cathodic
119
working volume of 100 mL respectively. The anode was made of three identical graphite
120
felts (6.0 cm length × 5.5 cm width × 1.0 cm thickness) and the cathode was a graphite plate
121
with a working surface area of 15 cm2.
122
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123 124
Fig. 1. The schematic diagram of a hybrid MFC-EFC system.
125 126
2.2 Experimental design
127
To setup a hybrid MFC-EFC system, the microbial anodes in both MFCs and the EFC
128
were enriched with EAB from the effluent of MFCs that had been running on real domestic
129
wastewater from Ulu Pandan Reclamation Plant (Singapore) for more than two years in our
130
previous study [24]. The EAB were fed with simulated wastewater prepared in 100 mM PBS
131
(pH 7.0) containing (mg L-1): CH3COONa, 500; NH4Cl, 310; KCl, 130; mineral salts medium
132
and vitamins [25]. Stable electricity output could be obtained after a two-week startup
133
operation. The catholyte for EES of formate from CO2 reduction in EFC, on the basis of 100
134
mM PBS at pH 6.0, contained 10 mM NaHCO3 as CO2 substrates and 1.0 mM nicotinamide
135
adenine dinucleotide (NADH, reduced form) as mediators. The deionized (DI) water used
136
for EES was boiled for 30 min to expel any dissolved CO2 species, and then cooled down to
137
room temperature for immediate preparation of catholyte under N2 gas. 7
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The first experiment was to investigate the electrochemical behaviors of immobilized
139
CbFDH on enzymatic cathode. Catalytic CV measurement was carried out between 0 V and
140
-1.0 V at a scan rate of 25 mV s-1 for 4 cycles [10, 12]. Effects of PolyNR films on electron
141
transfer and regeneration of mediators were studied by monitoring the time dependency of
142
reduction current (chronoamperometry) at a controlled cathode potential of -0.80 V for a long
143
period of 480 min. Both electrocatalytic voltammogram and chronoamperogram were
144
recorded with or without CO2 substrates in catholyte. Formate formation was detected in the
145
catholyte at the end of each electrochemical measurement.
146
The second experiment was to manipulate the efficient yield of formate by PolyNR on
147
enzymatic electrode. Three different poised potentials, i.e. -0.60 V, -0.80 V and -1.0 V were
148
applied by a potentiostat for 2.0 h respectively. At the end of EES, reduction products were
149
analyzed to understand the bioelectrochemical conversion of CO2 in the EFC.
150
The third experiment was carried out to evaluate the bioelectricity-generating capacity of
151
metallurgical (cupric) MFC stacks from wastewater. The cathode chambers of metallurgical
152
MFCs were spiked with Cu2+-containing solution ([Cu2+] = 100 mg L-1 prepared with
153
CuSO4 5H2O, pH = 3.0 adjusted by H2SO4) with NaCl of 5,850 mg L-1 as supporting
154
catholyte. The catholyte was flushed with N2 gas for 2 h to remove dissolved oxygen as a
155
potential electron acceptor other than Cu2+. The MFC reactors were stacked in two modes:
156
series or parallel-connected MFC stacks as power supplies. In the series-connected mode,
157
the microbial anode of one MFC reactor was connected to the cathode of an adjacent MFC,
158
eventually producing a cathode potential negative enough for CO2 reduction in the EFC. The
159
overall output of a series-connected MFC stack was equal to the sum voltage of each
160
individual MFC. In the parallel-connected mode, the microbial anodes of each MFC reactor
161
were connected together, thus introducing an enhanced electron flux to the cathode of EFC.
●
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The overall current intensity of a parallel-connected MFC stack was equal to the sum current
163
of each individual MFC.
164
The last experiment was to test the feasibility and sustainability of formate synthesis from
165
CO2 reduction in EFC driven by bioelectric power extracted from wastewater by MFC stacks.
166
A series and/or parallel-connected MFC stack was implemented to replace the potentiostat
167
utilized in the first and the second experiments. An enzymatic electrode with both
168
immobilized CbFDH and PolyNR was employed in the EFC. The manipulation for the
169
bioelectrochemical yield of formate was identical to that in the second experiment, but with
170
1, 2 or 3 stacked MFCs to achieve different cathode potentials. Samples were taken at 10,
171
20, 30, 40, 60, 90 and 120 min from the start of EES.
172
All the chemicals were purchased from Sigma-Aldrich (St. Louis, USA) and prepared in
173
DI water (Milli-Q, Academic system, Millipore Co., USA). Each experiment was carried out
174
in parallel and repeated for three times in a temperature-controlled room at 20 oC. All samples
175
were taken in triplicate.
176
2.3 Analyses and calculations
177
The output voltage (U in V) from metallurgical MFC stacks and electrode potential in the
178
EFC (V vs. Ag/AgCl in 3.0 M KCl) were recorded at 30 s intervals via a data acquisition
179
system (Adam 4017, Advantech Co., Ltd., China). In the MFC stacks, power generation
180
(U2/R in mW) was calculated via an external resistance (R in Ω); Polarization curves were
181
obtained by changing the external resistance in 12 steps from open circuit to 50 Ω and
182
stabling the voltage for at least 10 min at each step; The electric quantity (Q in C) was by
183
integrating current as a function of time. In the EFC, the reduction current density (I/Scat in
184
mA cm-2) was based on the surface area of cathode (Scat). The Faraday efficiency (FE) for
185
the formation of formate was calculated as follows: 9
ACCEPTED MANUSCRIPT 186
FE
2 F nFormate t
100%
(1)
Idt 0
187
where 2 is the number of electrons transferred for the formation of one molecule of formate
188
from CO2, F is the Faraday’s constant (96,485 C mol-1), nFormate is the moles of formate
189
harvested, I is the circuit current (A) and t is the reaction time (s).
190
The pH of aqueous solution was measured using a pH meter (PB-10, Sartorius AG,
191
Germany). Formate produced in EFC was qualitatively detected under automation on a 600
192
MHz NMR spectrometer (Premium Shielded Narrow Bore, Agilent Technologies, USA). An
193
HPLC (Agilent 1200 series, Agilent Technologies, USA), which was equipped with a C4
194
column (5.0 μm, 4.6 × 250 mm, GL Sciences Inc., Japan) and a DAD detector set at
195
wavelength of 210 nm, was used for the separation and quantitation of formate. Mobile phase
196
was 25 mM PBS (pH 2.0) at a constant flow rate of 0.80 mL min-1. All electrochemical
197
experiments were carried out on an IVIUMSTAT station (IVIUM Technologies, Eindhoven,
198
Netherlands) in three-electrode system with the fabricated enzymatic cathode as working
199
electrode, Ag/AgCl as reference electrode and Pt wire as counter electrode. For simplicity,
200
CO2 was used to denote all the dissolved species, i.e. [CO2]Total = [CO2]Gas + [H2CO3] +
201
[HCO3-] + [CO32-].
202
3. Results and discussion
203
3.1 Electrochemical behaviors of enzymatic cathode
204
Electrocatalytic voltammogram (Fig. 2a) shows that the enzymatic CO2 reduction initiates
205
at around -0.60 V, which is slightly higher than the calculated onset potential of -0.50 V (at
206
pH 6.0 in Fig. A.1). This finding implies that the overpotential required by
207
bioelectrochemical CO2 reduction can be reduced to as low as 0.10 V with the catalysis by 10
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CbFDH. Higher electromotive force is able to produce higher bioelectric current,
209
consequently contributing to higher yield of formate from CO2 reduction. The reduction
210
current increases rapidly as the driving force elevates from -0.60 V onwards, whose value
211
reaches -4.5 mA cm-2 at a poised potential as high as -1.0 V. There is no reduction current
212
observed in the absence of CO2 substrates. These above observations suggest that
213
electrocatalytic conversion of CO2 to formate can be efficiently catalyzed by CbFDH under
214
mild biological conditions.
215
Further, the bioelectrochemical behavior of GR electrode can be improved by the redox
216
active layers of PolyNR. Fig. 2b shows the enhanced catalytic current for bulk bioelectrolysis
217
trace on the PolyNR- coated cathode at a poised potential. In the chronoamperometry for
218
enzymatic CO2 reduction, an apparent reduction current, which cannot be detected without
219
CbFDH, is well maintained at around 2.0 mA cm-2 before fading away in the presence of
220
active PolyNR. The current density decreased by only 25% within an overall elapsed time of
221
480 min. In the absence of PolyNR layers, on the contrary, the reduction current gradually
222
disappears upon extended catalysis reactions. The increased current density indicated the
223
positive contribution from the bioelectrochemically active PolyNR layers. During the
224
electropolymerization process, an increase in current density for the redox peaks was
225
observed as PolyNR films formed on the surface of GR electrode (Fig. B.1). The redox active
226
polymeric layers are supposed to play an important role in efficient interfacial electron
227
transfer between the solid electrode surface of GR and the active site inside the CbFDH.
228
Hence the current density on a PolyNR-modified GR electrode is almost two times higher
229
than that on a simple GR as cathode material. Moreover, neutral red is a biocompatible redox
230
dye without inhibitory effect on enzymatic functions, unlike the commonly used toxic benzyl
231
viologen and methyl viologen in conventional assays [26]. These facts provide the evidences
232
that PolyNR can be confirmed as a promising promoter for the electrocatalytic CO2 11
ACCEPTED MANUSCRIPT 233
conversion to formate by CbFDH. When no CO2 substrates are added, negligible reduction
234
current can be detected on the enzymatic electrode. No formate was generated due to lack of
235
carbon sources. When bicarbonate was employed as CO2 substrates, there was an
236
accumulated formate concentration of 84.22 ± 6.53 mg L-1 with both PolyNR and CbFDH
237
after 480 min. These results proved the feasibility of CO2-to formate conversion in an MFC-
238
EFC system.
239
240
241 12
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Fig. 2. (a) Cyclic voltammetry of CO2 reduction on enzymatic electrode with immobilized
243
CbFDH. (b) Chronoamperometry of CO2 reduction on enzymatic electrode with immobilized
244
CbFDH and/or PolyNR at a poised potential of -0.80 V (vs. Ag/AgCl).
245 246
3.2 Specific and efficient formate generation in EFC
247
Fig. 3 illustrates the specific and efficient EES of formate from CO2 reduction in the EFC.
248
The only 1H NMR signal near 8.3 ppm (for all samples) is ascribed to the proton involved in
249
the molecular formula of HCOO-, suggesting formate being the specific reduction product
250
for EES. Using PolyNR as NADH-regenerators and CbFDH as biocatalysts, higher
251
production rates of formate could be obtained at more negative cathode potentials. When the
252
poised potentials increases from -0.60, -0.80 to -1.0 V, the average formate yield goes up
253
from 41.67 ± 4.16, 57.40 ± 4.60 to 64.71 ± 3.38 mg L-1 h-1 within a two-hour reaction period.
254
In comparison to the enzymatic electrode with PolyNR, the average formate yield reduces
255
nearly by half to 21.59 ± 4.56, 24.72 ± 4.03 and 28.06 ± 4.24 mg L-1 h-1 on the PolyNR-free
256
cathode under respective cathode potentials applied. Apart from the improvement on electron
257
transfer mentioned above, the deposited PolyNR exerts a lasting influence on the catalytic
258
electron flux for enzymatic CO2 reduction. NADH is a crucial mediator in EES, it is
259
consumed and oxidized to NAD+ coupled to the enzymatic reduction of CO2 to formate [13].
260
With the depletion of NADH, CO2-reduction course will be slowed down due to the limited
261
availability of mediators. The redox potential of PolyNR is slightly lower than that of NAD+
262
(-0.325 V vs. -0.320 V at pH 7.0, standard hydrogen electrode as reference) [27], it is an ideal
263
catalyst that can electrically reduce NAD+ to NADH. By using the electrochemically active
264
PolyNR as a reducing agent, the oxidized NAD+ can be recovered to NADH to further
265
mediate the CO2-reduction process [22]. More importantly, the fabricated electrode with 13
ACCEPTED MANUSCRIPT 266
immobilized CbFDH and coated PolyNR can be reused easily for more testing batches. A
267
net formate production rate higher than 20 mg L-1 h-1 could be insured after a long-term
268
running of 10 h (2.0 h per batch for 5 tests). This efficient CO2-to-formate capacity of
269
enzymatic cathode, due to the protected lifetime of immobilized CbFDH and regenerated
270
NADH mediator, contributes sustainably to formate generation from CO2.
271
272 273
Fig. 3. 1H NMR spectra for the CO2-reduction products and the yield of formate on the
274
enzymatic cathode at different poised potentials.
275 276
3.3 Electricity generation from metallurgical MFC stacks
277
To supply the EFC with a sufficient cathode potential and an input flux of electrons, MFCs
278
were connected in series and/or parallel to construct a MFC stack as an external power. As
279
shown in Fig 4a, an increased unit number tends to produce increasingly positive output
280
voltage from a series-connected MFC stack and more negative cathode potentials in the EFC.
281
When the MFC unit number is added up to n = 3, an overall output voltage as high as 1.59 ± 14
ACCEPTED MANUSCRIPT 282
0.12 V can be obtained to drive the CO2 reduction in EFC. The respective cathode potentials,
283
i.e. -0.74 ± 0.11, -0.93 ± 0.09 and -1.00 ± 0.11 V for n = 1, 2 and 3, are higher than the
284
practical onset potential of -0.60 V determined by CV measurement. This indicates that
285
sufficient motivation force can be harvested from the organic pollutants in wastewater to
286
support the lowered overpotential (around 0.10 V) for EES.
287
288
289 15
ACCEPTED MANUSCRIPT 290
Fig. 4. (a) Cathode potentials of EFC and output voltage produced by metallurgical MFC
291
stacks connected in series with different unit number. (b) Polarization curves of a 3-MFC
292
stack in series.
293 294
The maximum power output (Fig. 4b) from a three-MFC stack connected in series reaches
295
0.99 mW at a current intensity of 1.28 mA. Meanwhile, from a three-MFC stack in parallel
296
connection, an enhanced output flux of electrons (current intensity up to 8 mA) could be
297
acquired. Therefore, the metallurgic MFC stack is able to serve as an equivalent of an
298
external power supply for EES of formate from CO2 reduction in the EFC.
299
3.4 Sustainable EES driven by metallurgical MFC stacks
300
By accepting the electrons extracted from the organic matters in wastewater by MFCs,
301
considerable amount of CO2 wastes can be reduced to energy-rich formate in the EFC. As
302
presented in Fig. 5, the catalytic production of formate increases linearly as the CO2 reduction
303
reaction proceeds on the enzymatic electrode. The conversion course gradually slows down
304
after 60 min and eventually remains relatively constant in the last 30 min. A maximum
305
formate production rate of up to 100 mg L-1 h-1 was observed in the first 10 min of reaction.
306
Similar to the scenario in the potentiostat-EFC system, higher yield of formate could be
307
expected from the MFC-EFC system with more MFC units. At the end of 120-min testing
308
period, the accumulated concentration of formate from EES come to 61.88 ± 0.95, 56.82 ±
309
9.06 and 44.52 ± 9.82 mg L-1 powered by three, two and one-MFC stacks in series at the end
310
of EES (Fig. 5a). In the cathode chamber of EFC powered by a parallel-connected MFC
311
stack, the ascending formate concentration shares similar curve profiles to those in a series-
312
stacked MFC-EFC system (Fig. 5b). The formate productivity in EFC benefits less from the
313
increased unit number of MFC in a parallel stack, with a highest accumulated concentration 16
ACCEPTED MANUSCRIPT 314
of only 53.39 ± 8.47 mg L-1 at n = 3. This might be due to the reduced electrode potentials
315
when MFCs were parallel in a stack. The output bioelectric current rose twofold (n = 2) and
316
threefold (n = 3) as compared to a single MFC applied, but the electrode potential decreased
317
by posing more parallel MFCs accordingly. Based on these phenomena, a series-connected
318
MFC stack is more suitable to use in bioenergy generation for efficient CO2-to-formate
319
conversion, which makes an environmentally friendly way for specific formate production
320
from CO2 reduction and pollutant removal from wastewater.
321
17
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322
323 324
Fig. 5. Evolution of formate from bioelectrochemical CO2 reduction powered by (a) series-
325
connected and (b) parallel-connected MFC stacks with different unit number.
326 327
The MFC-EFC system is comparable in formate generation to a potentiostat-EFC system.
328
An average formate production rate of 59.13±3.85 mg L-1 h-1 could be achieved in the MFC-
329
EFC with a cathode potential of -1.00 ± 0.11 V imposed by a three-MFC stack connected in
330
series, which was slightly lower than that of 64.71 ± 3.38 mg L-1 h-1 in a potentiostat-EFC 18
ACCEPTED MANUSCRIPT 331
with a poised potential of -1.0 V. Hence the organic compounds in wastewater can be utilized
332
as efficient electron donors with MFCs for CO2 reduction in an EFC. To make the EES
333
process
334
carbonate/bicarbonate-medium feeding can be considered in the EFC for continuous formate
335
production.
336
3.5 Bioresource recovery and CO2 mitigation in hybrid MFC-EFC system
more
practical
for
application,
a
gaseous
CO2 source
or
constant
337
The hybrid MFC-EFC system has been proven to be energy-sustainable in specific
338
formate production for efficient CCSU. Table 1 summarizes the catalytic performance of
339
CbFDH in CO2 reduction to formate in the EFC by providing the enzymatic cathode with
340
electrons released from wastewater in MFC stacks. In the EFC powered by a three-MFC
341
stack in series, with a highest Faradaic efficiency of 70%, the average formate production
342
rate maximized at around 60 mg L-1 h-1 (or 1.18 ± 0.08 mg h-1 by one unit of CbFDH). If the
343
huge amount of CO2 (i.e. 1.21 × 104 tons day-1 emitted by wastewater treatment plants in
344
year 2025 as introduced earlier) can be captured in an aqueous system, thousand tons of
345
formate will be produced worldwide every day. The EFC also gains an advantage of energy
346
efficiency over the widely used metal catalysts which require excessive overpotential
347
(usually higher than -1.0 V) to initiate the electron transfer from cathode to CO2 species [28].
348
Consequently, bioelectrochemical CO2 sequestration and/or reduction therein lay a great
349
potential in sustainable development.
350 351
Table 1
352
Performance of the MFC-EFC system in CO2-to-formate conversion powered by
353
wastewater MFC unit (n)
Series 19
Parallel
ACCEPTED MANUSCRIPT n=1
n=2
n=3
n=2
n=3
46.11±5.34
57.12±5.18
59.13±3.85
47.19±7.41
56.01±6.89
0.35±0.04
0.43±0.04
0.45±0.03
0.36±0.06
0.42±0.05
0.92±0.11
1.14±0.10
1.18±0.08
0.94±0.15
1.12±0.14
57.36±7.60
65.58±6.56
69.94±4.34
37.14±3.60
26.72±3.26
13.25±1.74
12.00±1.58
20.04±2.49
33.30±2.55
Enzymatic fuel cell (EFC) Production rate (mg L-1 h-1) Production yield (mg mg CO2-1 h-1) Specific productivity (mg U CbFDH-1 h-1) Faraday efficiency (%)
Microbial fuel cell (MFC) stack Electric quantity (C)
13.71±2.05
354
Note: each data value represents an average at 95% confidence level over an experimental
355
period of 120 min.
356 357
The biodegradable organic pollutants in wastewater hold great promise as a variable
358
electron source for EES of formate. In our optimized hybrid biofuel cells, within a short
359
experimental period of 120 min, up to 2×1020 electrons are derived from the microbial
360
degradation of organic pollutants in low-strength wastewater. That is equivalent to 0.28 mM
361
CO2 reduction or formate generation (via a two-electron transfer reaction) based on an
362
electric quantity of 33 C from a three-MFC stack in parallel (total wastewater volume of 200
363
mL × 3). Domestic wastewater is a typical low-strength wastewater. The average
364
concentration of biodegradable organic matters was only 220 ± 34 mg L-1 (vs. > 10,000 mg
365
L-1 of industrial wastewater) in the water samples from Ulu Pandan Reclamation Plant
366
(Singapore). As for a conventional domestic wastewater treatment plant with a working
367
capacity of 10,000 m3 day-1, more than 120 kg of CO2/formate will be reduced/synthesized 20
ACCEPTED MANUSCRIPT 368
daily. This is commercially viable to meet the great market demand of million tons per year
369
for formic acid (formate) in the production of food additives and preservatives [29]. Thus,
370
domestic wastewater turns out to be a promising candidate to power MFC-MFC systems for
371
CO2 conversion to formate.
372
Furthermore, the real domestic wastewater has several attributes as a potential feedstock
373
for EES of valuable chemicals in a green pathway: Wastewater → CO2 → Formate (this
374
study) →∙Biofuels (future study). There are more biodegradable organic compounds and less
375
toxicant to support the growth of bacteria in MFCs. If the carbonate/bicarbonate-containing
376
effluent from the anode chambers of MFC (final products of organic matter degradation) can
377
be reused in the cathode of EFC in future study, the hybrid system shall be a more attractive
378
technology to make better use of the organic wastes in water rather than merely treating or
379
disposing them. However, proper operation like adjusting the pH of treated wastewater is
380
necessary to ensure an optimal working condition in the EFC. As of such, the constructed
381
MFC-EFC system is energy-and-performance efficient in mitigating the environmental
382
impact of CO2 and securing the molecular value of organic pollutants in wastewater.
383
4. Conclusion
384
The MFC-EFC system has been proven feasible to synthesize valuable chemical of
385
formate from CO2. On an appropriately fabricated enzymatic cathode with CbFDH and
386
PolyNR, sustainable CO2 reduction occurs at lowered overpotentials as low as 0.10 V.
387
Formate can be confirmed as the quantitative product of bioelectrochemical CO2 reduction.
388
Performance of metallurgical MFC stacked in both series and parallel has been investigated
389
to explore the potential application of CO2-to-formate conversion driven by the bioelectric
390
power supplied by water pollutants. Higher yield of formate can be obtained by inputting
391
flux of electrons from more MFC units. The optimal MFC-EFC system demonstrates 21
ACCEPTED MANUSCRIPT 392
competitive advantages in (1) oriented CO2 reduction, (2) efficient yield of formate and (3)
393
sustainable utilization of bioresource from wastewater.
394
Acknowledgements
395
The authors gratefully acknowledge the financial support from the National University of
396
Singapore, National Research Foundation and Economic Development Board (SPORE,
397
COY-15-EWI-RCFSA/N197-1) and Ministry of Education (R-143-000-519-112).
398
Appendices
399
Appendix A E-pH diagram of CO2 reduction by CbFDH
400
The E-pH diagram of CO2 reduction by immobilized CbFDH in aqueous system was
401
plotted based on the electrocatalytic voltammetry. Data have been fitted by using the Nernst
402
equation as follows:
403
E E
404
where Eθ = -0.21 V, pKRed = 3.75, pKOx1 = 6.39 and pKOx2 = 10.32 [10].
RT 1 K Ox1 / [ H ](1 K Ox 2 / [ H ]) ln 2F (1 K Re d / [ H ])[ H ]2
22
(A.1)
ACCEPTED MANUSCRIPT
405 406
Fig. A.1. pH-dependent reduction potential of CO2 in aqueous system. Potential values were
407
measured by the electrocatalytic voltammetry of immobilized CbFDH. The reduction
408
potentials (blue open circles) were recorded using 10 mM NaHCO3 and 10 mM formate in
409
100 mM PBS from pH 5.0 to 8.0 at 0.50 intervals. CV measurement was carried out as
410
indicated in Fig. 2a, but the enzymatic electrode rotated at a fixed rate of 2000 rpm.
411
23
ACCEPTED MANUSCRIPT 412
Appendix B Electro-polymerization of neutral red
413 414
Fig. B.1. Cyclic voltammetry for the electropolymerization of neutral red onto the graphite
415
rod electrode.
416
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Lijuan Zhang, Jacky Ong, Junyi Liu, Sam Fong Yau Li PII:
S0960-1481(17)30190-8
DOI:
10.1016/j.renene.2017.03.009
Reference:
RENE 8602
To appear in:
Enzymatic electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system
Received Date:
20 June 2016
Revised Date:
15 February 2017
Accepted Date:
02 March 2017
Please cite this article as: Lijuan Zhang, Jacky Ong, Junyi Liu, Sam Fong Yau Li, Enzymatic electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system, Enzymatic
electrosynthesis of formate from CO2 reduction in a hybrid biofuel cell system (2017), doi: 10.1016 /j.renene.2017.03.009
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ACCEPTED MANUSCRIPT
ACCEPTED MANUSCRIPT
Highlights
A MFC-EFC system was developed for bioelectrochemical CO2-to-formate conversion.
Electrocatalytic CO2 reduction was achieved with lowered overpotential by CbFDH.
Formate was bioelectro-synthesized from specific and sustainable CO2 reduction.
The hybrid system could be driven by bioelectric power from wastewater.
ACCEPTED MANUSCRIPT 1
Enzymatic electrosynthesis of formate from CO2 reduction in a
2
hybrid biofuel cell system
3
Lijuan Zhang a, Jacky Ong a, Junyi Liu a, Sam Fong Yau Li a,b*
4
a Department
5
117543, Singapore
6
b
7
117411, Singapore
of Chemistry, Faculty of Science, National University of Singapore, Singapore
NUS Environmental Research Institute, National University of Singapore, Singapore
8 9 10
*
11
Tel.: +65 65162681; fax: +65 67791691.
12
E-mail address: [email protected] (S.F.Y. Li).
Corresponding author.
1
ACCEPTED MANUSCRIPT 14
Abstract
15
To seek a sustainable way of CO2 sequestration and conversion, enzymatic electrosynthesis
16
(EES) of formate from CO2 reduction has been investigated in a hybrid biofuel cell system.
17
In an enzymatic fuel cell (EFC), waste CO2 species are specifically reduced to energy-rich
18
product of formate under mild biological conditions. Efficient formate production can be
19
achieved at lowered electrode potential owing to the electrochemically active participation
20
of formate dehydrogenase (CbFDH) as a biocatalyst. Electropolymerized neutral red
21
(PolyNR) is proven to be a promising modifier to enhance the electrochemical behavior of
22
enzymatic electrode, as well as a reducing reagent to regenerate mediator of NADH in
23
enzymatic CO2 reduction. Electrons for EES are extracted from the organic pollutants in
24
wastewater by microbial fuel cell (MFC) stacks arranged in series and/or parallel with
25
different unit numbers (n = 1, 2 and 3). The maximum formate production rate reaches around
26
60 mg L-1 h-1 with a Faraday efficiency of 70% in the EFC powered by a three-MFC stacked
27
in series. In view of practical applications, the hybrid MFC-EFC system has been
28
demonstrated to be advantageous in both product specificity and energy sustainability.
29
30 31
Keywords: Enzymatic fuel cell, Microbial fuel cell, CO2 reduction, Formate synthesis,
32
Formate dehydrogenase 2
ACCEPTED MANUSCRIPT 33
1. Introduction
34
With a rapid expansion of industrialization, anthropogenic carbon dioxide (CO2) that is
35
excessively emitted to atmosphere becomes an important greenhouse gas (GHG) in climate
36
change. GHG mitigation has been made a long-term commitment by many countries [1]. CO2
37
accounts for two thirds of the total GHG emitted by human activities, and is reported to be
38
the primary contributor to global warming. In the last century, global anthropogenic carbon
39
emission from fossil fuels has increased by around 10 times [2]. Among many industrial
40
emission sources, CO2 discharged from traditional wastewater treatment processes is of
41
particular interest to many environmental researchers. Tremendous amount of CO2, i.e. an
42
estimated 1.21 × 104 tons per day by 2025 [3], are released from the degradation of organic
43
pollutants in wastewater treatment plants worldwide. Although it is a causal factor in
44
warming the atmosphere and a waste product in treating wastewater, the inorganic CO2 can
45
be utilized as a substrate carbon source for synthesis of organic carbonates (e.g. formic acid,
46
acetate and methanol) [4, 5]. Thus far, efficient CO2 capture, sequestration and utilization
47
(CCSU) in wastewater treatment facilities is crucial to mitigate the potential impacts of CO2
48
on climate change and environment pollution.
49
To make the CCSU cycle virtuous, conversion of pollutants → CO2 → biofuels is a
50
desirable pathway to secure the molecular values of carbonaceous substrates in wastewater.
51
CO2 reduction to formate (or formic acid), which is the first step in methanol or methane
52
production route, is of particular interest in practical biofuel and bioenergy engineering.
53
Various CO2-to-formate conversion technologies have been well developed but are
54
challenged by different problems, such as the high energy consumption in electrochemical
55
reduction [6, 7] and the low reaction efficiency in bioconversion [8]. Recent studies illustrate
56
that efficient and specific synthesis of formate from CO2 reduction can be achieved by some 3
ACCEPTED MANUSCRIPT 57
biocatalysts in a bioelectrochemical system [9, 10]. Several whole microbial cells have
58
shown the ability to reduce CO2 to formate by decreasing the overpotential at electrodes.
59
However, the reaction rates were very low in most situations (experimental periods up to
60
days) [11]. Rapid and oriented electron movement from CO2 to formate has been proven to
61
be feasible by particular isolated enzymes such as formate dehydrogenase (FDH) in an
62
enzymatic fuel cell (EFC) [12, 13]. On the anode of an EFC, water or organic molecules are
63
oxidized, releasing protons and electrons. The electrons are transported from anode to
64
cathode where enzymatic electrosynthesis (EES) of formate takes place. On the cathode of
65
an EFC, the electrons are suggested to be transferred from solid electrode toward dissolved
66
CO2 species via the active sites of FDH, overcoming the high overpotential to activate CO2
67
reduction [14, 15]. Therefore, the energy input to an EFC can be decreased considerably
68
owing to the catalysis by FDH. Current FDH-reducing CO2 technology, however, suffers
69
from huge gaps in practical application. There are few well-applied systems in aqueous
70
conditions, especially in wastewater medium. And the limited studies on FDH reported only
71
partial CO2 reduction within deficient lifetime of enzyme. Moreover, there is a requirement
72
for electromotive force to drive EES for higher yield of formate. A driving force can be
73
expected from an external power supply such as a commonly used potentiostat [13, 16]. With
74
a growing demand for energy worldwide, however, a renewable electricity source is urgently
75
needed to be explored.
76
Microbial fuel cell (MFC) has been investigated to generate electricity by
77
electrochemically active bacteria (EAB) for more than a decade [17]. It has been extensively
78
considered as a promising source of power alternative to extract electrons from wastewater,
79
in which process the organic pollutants can be removed to produce clean water
80
simultaneously [18-20]. Nevertheless, as compared with the release of electrons, little
81
attention has been paid to the production of inorganic carbonaceous substrates such as 4
ACCEPTED MANUSCRIPT 82
carbonate/bicarbonate from organic pollutants degradation in which process CO2 might be
83
emitted to the atmosphere. Even less effort has been made to convert the produced CO2
84
wastes to valuable chemicals [21].
85
In this study, we aimed at enzymatic electrosynthesis of formate from CO2 reduction in a
86
hybrid MFC-EFC system. The electrons, i.e. CO2-reducing agents, were extracted from the
87
degradation of organic pollutants in wastewater by EAB in MFCs. A highly efficient and
88
reusable enzymatic cathode was fabricated for EES of formate in an EFC. FDH from
89
Candida boidinii (CbFDH) was immobilized on to surface of enzymatic cathode as
90
biocatalysts, and neutral red was deposited by electro-polymerization to enhance the
91
electrochemical properties of cathode. Specific and sustainable production of formate was
92
inspected at lowered electrode potentials in the EFC by implementing metallurgical MFC
93
stack in series or parallel connection as an external power supply.
94
2. Materials and methods
95
2.1 Hybrid MFC-EFC system
96
The hybrid biofuel cell system was constructed with an EFC and several series/parallel-
97
stacked metallurgical MFCs (unit number n = 1, 2 and 3 as shown in Fig. 1). Both EFC and
98
MFC were dual-chamber reactors separated by proton exchange membrane (PEM). The
99
chambers were sealed with silica gel to prevent any potential permeation of atmospheric CO2
100
and/or O2. All electrodes were carbon-based materials (Beijing Sanye Carbon Co., Ltd.,
101
China). They were firstly soaked in acetone overnight, thence in acid mixture of
102
H2SO4:HNO3 (1:3) for 6.0 h, and further cleaned in 0.20 M H2SO4 solution by cyclic
103
voltammetry (CV) between -0.50 V and +1.50 at 50 mV/s for 3 cycles. These clean electrodes
104
were subsequently annealed at 370 ℃ for 0.5 h, and equilibrated in 100 mM phosphate
5
ACCEPTED MANUSCRIPT 105
buffered saline (PBS, 11,472 mg L-1 Na2HPO4·2H2O and 4,904 mg L-1 NaH2PO4·H2O) prior
106
to use. The whole circuit was connected via pure titanium wires (> 99.9%).
107
The EFC reactor consisted of a cathodic and an anodic working volume of 20 mL each.
108
The anode was a single piece of highly porous graphite felt (2.5 cm length × 2.5 cm width ×
109
1.0 cm thickness). The enzymatic cathode was based on a simple graphite rod (GR, 1.5 mm
110
in diameter × 2.5 cm in length, Beijng Sanye Carbon Co., Ltd., China). Polymerized neutral
111
red (PolyNR) was electro-deposited onto the GR electrode in 100 mM PBS (pH 6.0) with
112
0.40 mM neutral red. CV was carried out between -0.80 V and +0.80 V at 50 mV/s for 100
113
cycles [22]. Enzyme (1.0 unit) was immobilized onto the surface of PolyNR-GR electrode
114
by modified Nafion micelles. The Nafion micelles (~5% in a mixture of lower aliphatic
115
alcohols and water) were pretreated with tetrabutyl ammonium bromide as reported
116
previously [23]. The fabricated enzymatic electrode was allowed to air dry at 4 ℃ for 4.0 h
117
and equilibrated in 100 mM PBS for at least 0.50 h before use.
118
The metallurgical MFC comprised an anodic working volume of 200 mL and a cathodic
119
working volume of 100 mL respectively. The anode was made of three identical graphite
120
felts (6.0 cm length × 5.5 cm width × 1.0 cm thickness) and the cathode was a graphite plate
121
with a working surface area of 15 cm2.
122
6
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123 124
Fig. 1. The schematic diagram of a hybrid MFC-EFC system.
125 126
2.2 Experimental design
127
To setup a hybrid MFC-EFC system, the microbial anodes in both MFCs and the EFC
128
were enriched with EAB from the effluent of MFCs that had been running on real domestic
129
wastewater from Ulu Pandan Reclamation Plant (Singapore) for more than two years in our
130
previous study [24]. The EAB were fed with simulated wastewater prepared in 100 mM PBS
131
(pH 7.0) containing (mg L-1): CH3COONa, 500; NH4Cl, 310; KCl, 130; mineral salts medium
132
and vitamins [25]. Stable electricity output could be obtained after a two-week startup
133
operation. The catholyte for EES of formate from CO2 reduction in EFC, on the basis of 100
134
mM PBS at pH 6.0, contained 10 mM NaHCO3 as CO2 substrates and 1.0 mM nicotinamide
135
adenine dinucleotide (NADH, reduced form) as mediators. The deionized (DI) water used
136
for EES was boiled for 30 min to expel any dissolved CO2 species, and then cooled down to
137
room temperature for immediate preparation of catholyte under N2 gas. 7
ACCEPTED MANUSCRIPT 138
The first experiment was to investigate the electrochemical behaviors of immobilized
139
CbFDH on enzymatic cathode. Catalytic CV measurement was carried out between 0 V and
140
-1.0 V at a scan rate of 25 mV s-1 for 4 cycles [10, 12]. Effects of PolyNR films on electron
141
transfer and regeneration of mediators were studied by monitoring the time dependency of
142
reduction current (chronoamperometry) at a controlled cathode potential of -0.80 V for a long
143
period of 480 min. Both electrocatalytic voltammogram and chronoamperogram were
144
recorded with or without CO2 substrates in catholyte. Formate formation was detected in the
145
catholyte at the end of each electrochemical measurement.
146
The second experiment was to manipulate the efficient yield of formate by PolyNR on
147
enzymatic electrode. Three different poised potentials, i.e. -0.60 V, -0.80 V and -1.0 V were
148
applied by a potentiostat for 2.0 h respectively. At the end of EES, reduction products were
149
analyzed to understand the bioelectrochemical conversion of CO2 in the EFC.
150
The third experiment was carried out to evaluate the bioelectricity-generating capacity of
151
metallurgical (cupric) MFC stacks from wastewater. The cathode chambers of metallurgical
152
MFCs were spiked with Cu2+-containing solution ([Cu2+] = 100 mg L-1 prepared with
153
CuSO4 5H2O, pH = 3.0 adjusted by H2SO4) with NaCl of 5,850 mg L-1 as supporting
154
catholyte. The catholyte was flushed with N2 gas for 2 h to remove dissolved oxygen as a
155
potential electron acceptor other than Cu2+. The MFC reactors were stacked in two modes:
156
series or parallel-connected MFC stacks as power supplies. In the series-connected mode,
157
the microbial anode of one MFC reactor was connected to the cathode of an adjacent MFC,
158
eventually producing a cathode potential negative enough for CO2 reduction in the EFC. The
159
overall output of a series-connected MFC stack was equal to the sum voltage of each
160
individual MFC. In the parallel-connected mode, the microbial anodes of each MFC reactor
161
were connected together, thus introducing an enhanced electron flux to the cathode of EFC.
●
8
ACCEPTED MANUSCRIPT 162
The overall current intensity of a parallel-connected MFC stack was equal to the sum current
163
of each individual MFC.
164
The last experiment was to test the feasibility and sustainability of formate synthesis from
165
CO2 reduction in EFC driven by bioelectric power extracted from wastewater by MFC stacks.
166
A series and/or parallel-connected MFC stack was implemented to replace the potentiostat
167
utilized in the first and the second experiments. An enzymatic electrode with both
168
immobilized CbFDH and PolyNR was employed in the EFC. The manipulation for the
169
bioelectrochemical yield of formate was identical to that in the second experiment, but with
170
1, 2 or 3 stacked MFCs to achieve different cathode potentials. Samples were taken at 10,
171
20, 30, 40, 60, 90 and 120 min from the start of EES.
172
All the chemicals were purchased from Sigma-Aldrich (St. Louis, USA) and prepared in
173
DI water (Milli-Q, Academic system, Millipore Co., USA). Each experiment was carried out
174
in parallel and repeated for three times in a temperature-controlled room at 20 oC. All samples
175
were taken in triplicate.
176
2.3 Analyses and calculations
177
The output voltage (U in V) from metallurgical MFC stacks and electrode potential in the
178
EFC (V vs. Ag/AgCl in 3.0 M KCl) were recorded at 30 s intervals via a data acquisition
179
system (Adam 4017, Advantech Co., Ltd., China). In the MFC stacks, power generation
180
(U2/R in mW) was calculated via an external resistance (R in Ω); Polarization curves were
181
obtained by changing the external resistance in 12 steps from open circuit to 50 Ω and
182
stabling the voltage for at least 10 min at each step; The electric quantity (Q in C) was by
183
integrating current as a function of time. In the EFC, the reduction current density (I/Scat in
184
mA cm-2) was based on the surface area of cathode (Scat). The Faraday efficiency (FE) for
185
the formation of formate was calculated as follows: 9
ACCEPTED MANUSCRIPT 186
FE
2 F nFormate t
100%
(1)
Idt 0
187
where 2 is the number of electrons transferred for the formation of one molecule of formate
188
from CO2, F is the Faraday’s constant (96,485 C mol-1), nFormate is the moles of formate
189
harvested, I is the circuit current (A) and t is the reaction time (s).
190
The pH of aqueous solution was measured using a pH meter (PB-10, Sartorius AG,
191
Germany). Formate produced in EFC was qualitatively detected under automation on a 600
192
MHz NMR spectrometer (Premium Shielded Narrow Bore, Agilent Technologies, USA). An
193
HPLC (Agilent 1200 series, Agilent Technologies, USA), which was equipped with a C4
194
column (5.0 μm, 4.6 × 250 mm, GL Sciences Inc., Japan) and a DAD detector set at
195
wavelength of 210 nm, was used for the separation and quantitation of formate. Mobile phase
196
was 25 mM PBS (pH 2.0) at a constant flow rate of 0.80 mL min-1. All electrochemical
197
experiments were carried out on an IVIUMSTAT station (IVIUM Technologies, Eindhoven,
198
Netherlands) in three-electrode system with the fabricated enzymatic cathode as working
199
electrode, Ag/AgCl as reference electrode and Pt wire as counter electrode. For simplicity,
200
CO2 was used to denote all the dissolved species, i.e. [CO2]Total = [CO2]Gas + [H2CO3] +
201
[HCO3-] + [CO32-].
202
3. Results and discussion
203
3.1 Electrochemical behaviors of enzymatic cathode
204
Electrocatalytic voltammogram (Fig. 2a) shows that the enzymatic CO2 reduction initiates
205
at around -0.60 V, which is slightly higher than the calculated onset potential of -0.50 V (at
206
pH 6.0 in Fig. A.1). This finding implies that the overpotential required by
207
bioelectrochemical CO2 reduction can be reduced to as low as 0.10 V with the catalysis by 10
ACCEPTED MANUSCRIPT 208
CbFDH. Higher electromotive force is able to produce higher bioelectric current,
209
consequently contributing to higher yield of formate from CO2 reduction. The reduction
210
current increases rapidly as the driving force elevates from -0.60 V onwards, whose value
211
reaches -4.5 mA cm-2 at a poised potential as high as -1.0 V. There is no reduction current
212
observed in the absence of CO2 substrates. These above observations suggest that
213
electrocatalytic conversion of CO2 to formate can be efficiently catalyzed by CbFDH under
214
mild biological conditions.
215
Further, the bioelectrochemical behavior of GR electrode can be improved by the redox
216
active layers of PolyNR. Fig. 2b shows the enhanced catalytic current for bulk bioelectrolysis
217
trace on the PolyNR- coated cathode at a poised potential. In the chronoamperometry for
218
enzymatic CO2 reduction, an apparent reduction current, which cannot be detected without
219
CbFDH, is well maintained at around 2.0 mA cm-2 before fading away in the presence of
220
active PolyNR. The current density decreased by only 25% within an overall elapsed time of
221
480 min. In the absence of PolyNR layers, on the contrary, the reduction current gradually
222
disappears upon extended catalysis reactions. The increased current density indicated the
223
positive contribution from the bioelectrochemically active PolyNR layers. During the
224
electropolymerization process, an increase in current density for the redox peaks was
225
observed as PolyNR films formed on the surface of GR electrode (Fig. B.1). The redox active
226
polymeric layers are supposed to play an important role in efficient interfacial electron
227
transfer between the solid electrode surface of GR and the active site inside the CbFDH.
228
Hence the current density on a PolyNR-modified GR electrode is almost two times higher
229
than that on a simple GR as cathode material. Moreover, neutral red is a biocompatible redox
230
dye without inhibitory effect on enzymatic functions, unlike the commonly used toxic benzyl
231
viologen and methyl viologen in conventional assays [26]. These facts provide the evidences
232
that PolyNR can be confirmed as a promising promoter for the electrocatalytic CO2 11
ACCEPTED MANUSCRIPT 233
conversion to formate by CbFDH. When no CO2 substrates are added, negligible reduction
234
current can be detected on the enzymatic electrode. No formate was generated due to lack of
235
carbon sources. When bicarbonate was employed as CO2 substrates, there was an
236
accumulated formate concentration of 84.22 ± 6.53 mg L-1 with both PolyNR and CbFDH
237
after 480 min. These results proved the feasibility of CO2-to formate conversion in an MFC-
238
EFC system.
239
240
241 12
ACCEPTED MANUSCRIPT 242
Fig. 2. (a) Cyclic voltammetry of CO2 reduction on enzymatic electrode with immobilized
243
CbFDH. (b) Chronoamperometry of CO2 reduction on enzymatic electrode with immobilized
244
CbFDH and/or PolyNR at a poised potential of -0.80 V (vs. Ag/AgCl).
245 246
3.2 Specific and efficient formate generation in EFC
247
Fig. 3 illustrates the specific and efficient EES of formate from CO2 reduction in the EFC.
248
The only 1H NMR signal near 8.3 ppm (for all samples) is ascribed to the proton involved in
249
the molecular formula of HCOO-, suggesting formate being the specific reduction product
250
for EES. Using PolyNR as NADH-regenerators and CbFDH as biocatalysts, higher
251
production rates of formate could be obtained at more negative cathode potentials. When the
252
poised potentials increases from -0.60, -0.80 to -1.0 V, the average formate yield goes up
253
from 41.67 ± 4.16, 57.40 ± 4.60 to 64.71 ± 3.38 mg L-1 h-1 within a two-hour reaction period.
254
In comparison to the enzymatic electrode with PolyNR, the average formate yield reduces
255
nearly by half to 21.59 ± 4.56, 24.72 ± 4.03 and 28.06 ± 4.24 mg L-1 h-1 on the PolyNR-free
256
cathode under respective cathode potentials applied. Apart from the improvement on electron
257
transfer mentioned above, the deposited PolyNR exerts a lasting influence on the catalytic
258
electron flux for enzymatic CO2 reduction. NADH is a crucial mediator in EES, it is
259
consumed and oxidized to NAD+ coupled to the enzymatic reduction of CO2 to formate [13].
260
With the depletion of NADH, CO2-reduction course will be slowed down due to the limited
261
availability of mediators. The redox potential of PolyNR is slightly lower than that of NAD+
262
(-0.325 V vs. -0.320 V at pH 7.0, standard hydrogen electrode as reference) [27], it is an ideal
263
catalyst that can electrically reduce NAD+ to NADH. By using the electrochemically active
264
PolyNR as a reducing agent, the oxidized NAD+ can be recovered to NADH to further
265
mediate the CO2-reduction process [22]. More importantly, the fabricated electrode with 13
ACCEPTED MANUSCRIPT 266
immobilized CbFDH and coated PolyNR can be reused easily for more testing batches. A
267
net formate production rate higher than 20 mg L-1 h-1 could be insured after a long-term
268
running of 10 h (2.0 h per batch for 5 tests). This efficient CO2-to-formate capacity of
269
enzymatic cathode, due to the protected lifetime of immobilized CbFDH and regenerated
270
NADH mediator, contributes sustainably to formate generation from CO2.
271
272 273
Fig. 3. 1H NMR spectra for the CO2-reduction products and the yield of formate on the
274
enzymatic cathode at different poised potentials.
275 276
3.3 Electricity generation from metallurgical MFC stacks
277
To supply the EFC with a sufficient cathode potential and an input flux of electrons, MFCs
278
were connected in series and/or parallel to construct a MFC stack as an external power. As
279
shown in Fig 4a, an increased unit number tends to produce increasingly positive output
280
voltage from a series-connected MFC stack and more negative cathode potentials in the EFC.
281
When the MFC unit number is added up to n = 3, an overall output voltage as high as 1.59 ± 14
ACCEPTED MANUSCRIPT 282
0.12 V can be obtained to drive the CO2 reduction in EFC. The respective cathode potentials,
283
i.e. -0.74 ± 0.11, -0.93 ± 0.09 and -1.00 ± 0.11 V for n = 1, 2 and 3, are higher than the
284
practical onset potential of -0.60 V determined by CV measurement. This indicates that
285
sufficient motivation force can be harvested from the organic pollutants in wastewater to
286
support the lowered overpotential (around 0.10 V) for EES.
287
288
289 15
ACCEPTED MANUSCRIPT 290
Fig. 4. (a) Cathode potentials of EFC and output voltage produced by metallurgical MFC
291
stacks connected in series with different unit number. (b) Polarization curves of a 3-MFC
292
stack in series.
293 294
The maximum power output (Fig. 4b) from a three-MFC stack connected in series reaches
295
0.99 mW at a current intensity of 1.28 mA. Meanwhile, from a three-MFC stack in parallel
296
connection, an enhanced output flux of electrons (current intensity up to 8 mA) could be
297
acquired. Therefore, the metallurgic MFC stack is able to serve as an equivalent of an
298
external power supply for EES of formate from CO2 reduction in the EFC.
299
3.4 Sustainable EES driven by metallurgical MFC stacks
300
By accepting the electrons extracted from the organic matters in wastewater by MFCs,
301
considerable amount of CO2 wastes can be reduced to energy-rich formate in the EFC. As
302
presented in Fig. 5, the catalytic production of formate increases linearly as the CO2 reduction
303
reaction proceeds on the enzymatic electrode. The conversion course gradually slows down
304
after 60 min and eventually remains relatively constant in the last 30 min. A maximum
305
formate production rate of up to 100 mg L-1 h-1 was observed in the first 10 min of reaction.
306
Similar to the scenario in the potentiostat-EFC system, higher yield of formate could be
307
expected from the MFC-EFC system with more MFC units. At the end of 120-min testing
308
period, the accumulated concentration of formate from EES come to 61.88 ± 0.95, 56.82 ±
309
9.06 and 44.52 ± 9.82 mg L-1 powered by three, two and one-MFC stacks in series at the end
310
of EES (Fig. 5a). In the cathode chamber of EFC powered by a parallel-connected MFC
311
stack, the ascending formate concentration shares similar curve profiles to those in a series-
312
stacked MFC-EFC system (Fig. 5b). The formate productivity in EFC benefits less from the
313
increased unit number of MFC in a parallel stack, with a highest accumulated concentration 16
ACCEPTED MANUSCRIPT 314
of only 53.39 ± 8.47 mg L-1 at n = 3. This might be due to the reduced electrode potentials
315
when MFCs were parallel in a stack. The output bioelectric current rose twofold (n = 2) and
316
threefold (n = 3) as compared to a single MFC applied, but the electrode potential decreased
317
by posing more parallel MFCs accordingly. Based on these phenomena, a series-connected
318
MFC stack is more suitable to use in bioenergy generation for efficient CO2-to-formate
319
conversion, which makes an environmentally friendly way for specific formate production
320
from CO2 reduction and pollutant removal from wastewater.
321
17
ACCEPTED MANUSCRIPT
322
323 324
Fig. 5. Evolution of formate from bioelectrochemical CO2 reduction powered by (a) series-
325
connected and (b) parallel-connected MFC stacks with different unit number.
326 327
The MFC-EFC system is comparable in formate generation to a potentiostat-EFC system.
328
An average formate production rate of 59.13±3.85 mg L-1 h-1 could be achieved in the MFC-
329
EFC with a cathode potential of -1.00 ± 0.11 V imposed by a three-MFC stack connected in
330
series, which was slightly lower than that of 64.71 ± 3.38 mg L-1 h-1 in a potentiostat-EFC 18
ACCEPTED MANUSCRIPT 331
with a poised potential of -1.0 V. Hence the organic compounds in wastewater can be utilized
332
as efficient electron donors with MFCs for CO2 reduction in an EFC. To make the EES
333
process
334
carbonate/bicarbonate-medium feeding can be considered in the EFC for continuous formate
335
production.
336
3.5 Bioresource recovery and CO2 mitigation in hybrid MFC-EFC system
more
practical
for
application,
a
gaseous
CO2 source
or
constant
337
The hybrid MFC-EFC system has been proven to be energy-sustainable in specific
338
formate production for efficient CCSU. Table 1 summarizes the catalytic performance of
339
CbFDH in CO2 reduction to formate in the EFC by providing the enzymatic cathode with
340
electrons released from wastewater in MFC stacks. In the EFC powered by a three-MFC
341
stack in series, with a highest Faradaic efficiency of 70%, the average formate production
342
rate maximized at around 60 mg L-1 h-1 (or 1.18 ± 0.08 mg h-1 by one unit of CbFDH). If the
343
huge amount of CO2 (i.e. 1.21 × 104 tons day-1 emitted by wastewater treatment plants in
344
year 2025 as introduced earlier) can be captured in an aqueous system, thousand tons of
345
formate will be produced worldwide every day. The EFC also gains an advantage of energy
346
efficiency over the widely used metal catalysts which require excessive overpotential
347
(usually higher than -1.0 V) to initiate the electron transfer from cathode to CO2 species [28].
348
Consequently, bioelectrochemical CO2 sequestration and/or reduction therein lay a great
349
potential in sustainable development.
350 351
Table 1
352
Performance of the MFC-EFC system in CO2-to-formate conversion powered by
353
wastewater MFC unit (n)
Series 19
Parallel
ACCEPTED MANUSCRIPT n=1
n=2
n=3
n=2
n=3
46.11±5.34
57.12±5.18
59.13±3.85
47.19±7.41
56.01±6.89
0.35±0.04
0.43±0.04
0.45±0.03
0.36±0.06
0.42±0.05
0.92±0.11
1.14±0.10
1.18±0.08
0.94±0.15
1.12±0.14
57.36±7.60
65.58±6.56
69.94±4.34
37.14±3.60
26.72±3.26
13.25±1.74
12.00±1.58
20.04±2.49
33.30±2.55
Enzymatic fuel cell (EFC) Production rate (mg L-1 h-1) Production yield (mg mg CO2-1 h-1) Specific productivity (mg U CbFDH-1 h-1) Faraday efficiency (%)
Microbial fuel cell (MFC) stack Electric quantity (C)
13.71±2.05
354
Note: each data value represents an average at 95% confidence level over an experimental
355
period of 120 min.
356 357
The biodegradable organic pollutants in wastewater hold great promise as a variable
358
electron source for EES of formate. In our optimized hybrid biofuel cells, within a short
359
experimental period of 120 min, up to 2×1020 electrons are derived from the microbial
360
degradation of organic pollutants in low-strength wastewater. That is equivalent to 0.28 mM
361
CO2 reduction or formate generation (via a two-electron transfer reaction) based on an
362
electric quantity of 33 C from a three-MFC stack in parallel (total wastewater volume of 200
363
mL × 3). Domestic wastewater is a typical low-strength wastewater. The average
364
concentration of biodegradable organic matters was only 220 ± 34 mg L-1 (vs. > 10,000 mg
365
L-1 of industrial wastewater) in the water samples from Ulu Pandan Reclamation Plant
366
(Singapore). As for a conventional domestic wastewater treatment plant with a working
367
capacity of 10,000 m3 day-1, more than 120 kg of CO2/formate will be reduced/synthesized 20
ACCEPTED MANUSCRIPT 368
daily. This is commercially viable to meet the great market demand of million tons per year
369
for formic acid (formate) in the production of food additives and preservatives [29]. Thus,
370
domestic wastewater turns out to be a promising candidate to power MFC-MFC systems for
371
CO2 conversion to formate.
372
Furthermore, the real domestic wastewater has several attributes as a potential feedstock
373
for EES of valuable chemicals in a green pathway: Wastewater → CO2 → Formate (this
374
study) →∙Biofuels (future study). There are more biodegradable organic compounds and less
375
toxicant to support the growth of bacteria in MFCs. If the carbonate/bicarbonate-containing
376
effluent from the anode chambers of MFC (final products of organic matter degradation) can
377
be reused in the cathode of EFC in future study, the hybrid system shall be a more attractive
378
technology to make better use of the organic wastes in water rather than merely treating or
379
disposing them. However, proper operation like adjusting the pH of treated wastewater is
380
necessary to ensure an optimal working condition in the EFC. As of such, the constructed
381
MFC-EFC system is energy-and-performance efficient in mitigating the environmental
382
impact of CO2 and securing the molecular value of organic pollutants in wastewater.
383
4. Conclusion
384
The MFC-EFC system has been proven feasible to synthesize valuable chemical of
385
formate from CO2. On an appropriately fabricated enzymatic cathode with CbFDH and
386
PolyNR, sustainable CO2 reduction occurs at lowered overpotentials as low as 0.10 V.
387
Formate can be confirmed as the quantitative product of bioelectrochemical CO2 reduction.
388
Performance of metallurgical MFC stacked in both series and parallel has been investigated
389
to explore the potential application of CO2-to-formate conversion driven by the bioelectric
390
power supplied by water pollutants. Higher yield of formate can be obtained by inputting
391
flux of electrons from more MFC units. The optimal MFC-EFC system demonstrates 21
ACCEPTED MANUSCRIPT 392
competitive advantages in (1) oriented CO2 reduction, (2) efficient yield of formate and (3)
393
sustainable utilization of bioresource from wastewater.
394
Acknowledgements
395
The authors gratefully acknowledge the financial support from the National University of
396
Singapore, National Research Foundation and Economic Development Board (SPORE,
397
COY-15-EWI-RCFSA/N197-1) and Ministry of Education (R-143-000-519-112).
398
Appendices
399
Appendix A E-pH diagram of CO2 reduction by CbFDH
400
The E-pH diagram of CO2 reduction by immobilized CbFDH in aqueous system was
401
plotted based on the electrocatalytic voltammetry. Data have been fitted by using the Nernst
402
equation as follows:
403
E E
404
where Eθ = -0.21 V, pKRed = 3.75, pKOx1 = 6.39 and pKOx2 = 10.32 [10].
RT 1 K Ox1 / [ H ](1 K Ox 2 / [ H ]) ln 2F (1 K Re d / [ H ])[ H ]2
22
(A.1)
ACCEPTED MANUSCRIPT
405 406
Fig. A.1. pH-dependent reduction potential of CO2 in aqueous system. Potential values were
407
measured by the electrocatalytic voltammetry of immobilized CbFDH. The reduction
408
potentials (blue open circles) were recorded using 10 mM NaHCO3 and 10 mM formate in
409
100 mM PBS from pH 5.0 to 8.0 at 0.50 intervals. CV measurement was carried out as
410
indicated in Fig. 2a, but the enzymatic electrode rotated at a fixed rate of 2000 rpm.
411
23
ACCEPTED MANUSCRIPT 412
Appendix B Electro-polymerization of neutral red
413 414
Fig. B.1. Cyclic voltammetry for the electropolymerization of neutral red onto the graphite
415
rod electrode.
416
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