Abstract
Rather than the conventional concept of viewing conductive carbon black (CB) to be chemically inert in microbial electrochemical cells (MECs), here we confirmed the redox activity of CB for its feasibility as an electron sink in the microbial battery (MB). Acting as the cathode of a MB, the solid-state CB electrode showed the highest electron capacity equivalent of 18.58 ± 0.46 C/g for the unsintered one and the lowest capacity of 2.29 ± 0.48 C/g for the one sintered under 100% N2 atmosphere. The capacity vibrations of CBs were strongly in coincidence with the abundances of C=O moiety caused by different pretreatments and it implied one plausible mechanism based on CB’s surface functionality for its electron capturing. Once subjected to electron saturation, CB could be completely regenerated by different strategies in terms of electrochemical discharging or donating electrons to biologically-catalyzed nitrate reduction. Surface characterization also revealed that CB’s regeneration fully depended on the reversible shift of C=O moiety, further confirming the functionality-based mechanism for CB’s feasibility as the role of MB’s cathode. Moreover, resilience tests demonstrated that CB cathode was robust for the multi-cycles charging-discharging operations. These results imply that CB is a promising alternative material for the solid-state cathode in MBs.
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Introduction
Nowadays increasing energy demand and adverse effects of energy extraction from irreversible fossil consumption on environment have catalyzed scientific focus on deriving energy from organic reservoirs (especially organic wastes e.g., domestic wastewater) via biotechnology. Among various microbial technologies, microbial fell cells (MFCs) offer an option for direct electricity harvest from organics by anodic microbial catalysis and have been used to recover electrical energy from domestic sewage1, 2. Originally consumable agents, such as potassium ferricyanide, potassium permanganate, were used in the cathode of MFCs as electron acceptors, while O2 was identified as an optimal alternative afterwards for practical applications as it is inexhaustible from ambient air3. However, O2 functioning as terminal acceptor has some disadvantages: (1) limited kinetics of the oxygen reduction especially when reaction occurs in solution that oxygen has low solubility thus low accessibility4; (2) high voltage losses at the cathode due to the high overpotential1; (3) charge losses resulted from aerobic metabolism as dissolved oxygen diffuses from the cathode compartment into the anode compartment5.
To eliminate the defects of oxygen-based MFCs, Xie et al.6 described a microbial battery (MB), a new type of microbial electrochemical cells (MECs), that was designed to use the solid-state cathode itself instead of O2 as electron acceptor. The MBs are superior to MFCs by improving energy recovery efficiency since charge loss can be prevented without O2 involvement and voltage loss can be reduced by the re-oxidation of electrode reaction rather than O2 reduction6. The operational concept of the solid-state cathode is like that of a rechargeable battery, which is technically dependent on the reversible capabilities of cathodic materials. Thus the configuration challenge for MBs is to find a right cathode material that is rechargeable and at the same time with the suitable redox-potential to ensure the microbial-mediated electron transfer from organic reservoirs into cathode; other significant considerations include robustness, cost-effectiveness, and energy-effective regeneration6. Based on these principles, a prussian blue cathode7 was further developed versus the originally-constructed silver-oxide electrode for a practical application implication, for the fact that silver is costly, and regeneration of silver oxidation is thermodynamically unfavorable and energy-consuming6. Enlightened by this, identification of more competing materials for solid-state cathode is quite desirable.
Carbon materials, such as carbon black (CB), activated carbon (AC), graphite, carbon cloth, carbon felt, and reticulated vitreous carbon, are the most commonly used electrode materials for MECs because of their low price, good biocompatibility and chemical stability8, 9. However, these properties have aroused a general illusion in the field of bioelectrochemistry that all carbon materials are chemically inert. For example, in several studie10,11,12, CB was fabricated into the air layer of the synthetic air-cathode in single-chamber MFCs, the role of which was viewed to be inert for gas diffusion rather than active catalysis. This illusion is also strengthened by the focus on the application of carbon materials (e.g., AC and CB) for contaminant remediation, and they are viewed as passive adsorbents13,14,15.
However, small portion of recent studies have broken this prominent belief and many carbon materials, including CB, AC, graphite, char, carbon nanotubes, and graphene oxide, were proved to be active in mediating specific oxidation and reduction reactions16,17,18. In the study by Robles et al.19, AC was used as a redox mediator for the enhanced degradation of azo dye in a MEC; Dong et al.20 first reported that AC functioned as a cheap oxygen reduction catalyst for efficient electricity generation in an air-cathode MFC; in a similar publication21, wood-derived carbon material was applied for an MFC anode to achieve satisfactory power density. Although the specific mechanisms for the active roles of carbon materials in these MECs were not fully understood, they actually have played a catalytic role to accelerate electron transfer rate. Some attributed these performance contributions to physical resolutions (such as high conductivity22 or high porousness23) of carbon materials), while some others attributed them to chemically active property of some carbon materials based on their redox-active surface functionalities17. Based on this indication, chemically-active carbon materials are potentially able to capture and store soluble electrons, and therefore play the role as solid-state electron donor.
Considering that the carbon material is one of the most promising nonprecious materials as it is both inexpensive and renewably accessible from waste biomass23, it may provide a more practical outlet for the application development in MBs. Therefore, in present work, we studied CB as a typical example of the carbon material to investigate the practicality of CB as the solid-state cathode of MBs. More specifically, we determined if CB can act as electron sink for biodegradable organic extraction and if its electron-capture ability can be regenerated by re-oxidation of CB. Besides, the functionality-based mechanism correlated to CB’s electron-transfer role was also elucidated based on the experimental results.
Results and Discussion
Electrochemical Redox Characterization of CB Cathode
The electrochemical redox properties of solid-state CB electrodes as characterized by LSVs are shown in Fig. 1. Curves exhibited active interactions on the interface between all four CB electrodes and electrolyte. As no hydrogen evolution was detected on the CB electrodes (the details of confirmation experiment and specific discussion can be found in Supplementary Information), it suggested the strong electron-capturing capability of CB electrodes. Similar to the results of LSVs, cyclic voltammetry curves (CVs) also showed obvious reduction peaks (Fig. S4a), rather than forming a rectangular shape of the voltammetry characteristics. It meant the electron-capturing capability of CB was from its redox-active property rather than double layer capacitance.
However, the open circuit potentials (OCPs) of four CB electrodes varied (Fig. 1a), which meant the different redox status of differently-treated CBs. We noted that the OCPs of electrodes were all positive than 0 V vs Ag/AgCl, and it implied the accessible turnover potential of CB’s electron-accepting characterization, which is a prerequisite for the selection of MB’s cathode material6. Theoretically, for a spontaneous electron transfer from anodic reservoirs to cathodes in MECs, a more positive oxidation potential compared with the anodic potential of −0.4 V (vs Ag/AgCl electrode) is compulsory for cathodic electron acceptors2. Thus, the potentials for electron-accepting turnover shown in the LSV curves meant that CB was capable of capturing electrons in MBs in terms of a microbial-mediated organic extraction.
Referring to surface functionalities of CBs, these findings were confirmed by FTIR analysis (Fig. 2 and Table S2). Readers are referred to the Supplementary Information for a more detailed discussion of these results. To summarize, (i) the notable vibration of C=C at 1440 cm−1 indicative of the existence of aromatic C24, 25 and the vibration of C=O at 1630 cm−1 indicative of a strong presence of quinone structures25, 26 both confirmed CB to be an excellent electron sink27, 28. (ii) The unsintered CB electrode wholly preserved the absorbance of the pristine CB with unsaturated C=C band and C=O, while only the quinone C=O band remained for the sintered electrodes. These results indicated that the functionality of the CB electrodes arose from the inherent nature of CB, and their activity varied according to the functional group shift.
XPS spectra (Fig. 3 and Table S3; detailed discussion also in Supplementary Information) further demonstrated the existence of the quinone C=O moieties for the unsintered and sintered CBs29, 30. Previous studies have shown that the surface functionalities of carbon materials, including hydroxyl, carbonyl, carboxyl, and lactone moieties, can lead to reversible redox reactions, which can be expressed as follows31, 32:
Thus the presence of C=O moieties, the indication of a strong electron-accepting capability of CB and no hydrogen evolution confirmed that the chemical activity of CB was closely related to its surface chemistry. Moreover, the C=O moiety abundance discrepancy (Fig. 3) of differently treated CB electrodes may explain their different redox status.
Notable changes were observed for the LSV curves of charged electrodes (Fig. 1b). The significantly varied current intensities all underwent a notable drop to a similar level, and the strong reductive tendencies disappeared. The same phenomenon was also observed for CVs (Fig. S4b). This ‘inert appearance’ arose from the electron saturation of the electrodes, was confirmed by decreases of the C=O moiety abundance for different electrodes to a similar percentage and other moieties providing similar proportion after electrodes being charged (Fig. S7). This proof was also in agreement with the final redox status of differently-treated CB in terms of the similar OCPs (around −0.9 V vs Ag/AgCl) (Fig. 1b). Meanwhile, the variation trend of OCP, i.e decreasing from different vales to the similar one, signified the conversion of CB by electron saturation and further proved the CB’s capability of electron-capturing. Further decreasing reduction potential resulted in hydrogen evolution on the surface of charged electrodes (the details discussion can be found in Supplementary Information) and it further proved CB’s chemical activity by no observation of hydrogen evolutions (with potential positive than −1.0 V) on the surface of uncharged electrodes (Fig. S2).
Once applied in MBs, all pre-treated solid-state electrodes acted as electron sink for power output (Fig. 4a), which was the direct proof that CB can be an alternative material in MBs. Moreover, the varied current curves demonstrated that different electrochemical capacities of CB were obtained through different treatments. Further quantitative analysis (Table 1, average values calculated from Fig. 4 and Fig. S8) revealed that unsintered CB exhibited the highest electron equivalent capacity of 18.58 ± 0.46 C/g. Thermal treatment was prejudicial to the preservation of capacity. CB sintered with N2 displayed the poorest capacity of 2.29 ± 0.48 C/g, while sintering with O2 was relatively conducive to maintaining electron-acceptance, with a capacity of 8.97 ± 0.19 C/g obtained under 70% O2 and 30% N2 and 8.26 ± 0.13 C/g under 30% O2 and 70% N2. XPS results showed that the contents of quinone C=O moiety obtained by different treatments on CB corresponded to their different capacities, i.e., the unsintered electrode contained the highest percentage of 63.2%, while the percentage significantly decreased to 27.6%, 22.8%, and 10.8% after thermal treatment as the proportion of N2 in the sintering atmosphere was increased (Fig. 3a–d). The correlation between CB’s capacity and its C=O moiety abundance proved the role of quinone C=O as electron sink that was indicated by previous LSV characterization, and also proved the indication in our study of a moiety-based mechanism for CB’s feasibility as a cathode material in MBs.
However, as a material aimed to be practically used in MBs for charge storage, we found the specific capacity of CB in our work is far from satisfying the practical application from weight and size perspectives, especially compared to metal materials normally used in the cathode of conventional batteries (Table 2)33, 34. Compared with the conventional battery completely focusing on the energy storage, MBs aim at energy acquirement as well as wastewater treatment as organic reservoirs. Thus the superior properties in terms of economy, biocompatibility and anti-corrosion make carbon materials the better candidates applied in MBs if their specific capacities can be improved. Meanwhile, we learnt the capacity storage of CB was determined by various factors such as surface structure, surface area, surface functionalities and some of them or some other carbon materials have even shown the specific capacity comparable to normally used metal materials (Table 2)33,34,35,36,37. Thus efforts including changing the configuration of electrode to increase its surface area, doping of active element (such as O, S) to further improve active sites of CB may potentially enhance the specific capacity of CB to truly satisfy its application in MBs. And these are what we further concentrate on to expand our current research to an application area.
Regeneration of CB Cathodes
The recyclable utilization of cathode is another element for the practical application, which means CB-based electrodes should be regenerated once subjected to electron saturation. As expected, CB’s electron-capturing ability could be reproduced by discharging the CB samples through a reverse electrochemical oxidation (Fig. 4b–d). The re-charging current curves of the discharged CB samples significantly varied depending on the discharge parameters, i.e., 0.1-mA (Fig. 4b), 0.5-mA (Fig. 4c), or 1.0-mA constant current (Fig. 4d). The greatest influence was observed on the CB electrode sintered in N2 only, the capacity of which doubled after it was discharged at 0.1 mA constant current and further grew to 5.99 ± 0.18 C/g after being discharged at 0.5 mA and 7.02 ± 0.86 C/g at 1.0 mA. Despite the constant increase in capacity induced by the increased discharge current, the highest growths (at 1.0 mA discharging current) of only 9.9% for the unsintered, 21.8% for 30% O2 sintered, and 16.81% for 70% O2 sintered CB was obtained, respectively. Given the relatively low amount of C=O on the initial 100% N2 sintered CB, the sharp capacity increase was supposed to have derived from electrochemical activation of functional moieties acting as the electron sink, while the other treated CBs possessed relatively more active moieties, which were not prone to activation. Indeed, the XPS results showed that the C=O functional moieties of different electrode categories all recovered, to 59.6% for the unsintered CB, 30.6% for the 100% N2 sintered CB, 50.5% for the 30% O2 sintered CB, and 53.3% for the 70% O2 sintered CB (Fig. S9). The electrode sintered with pure N2 exhibited the largest increase in C=O moiety abundance by discharging, which was the direct proof of its maximum capacity increase after electrochemical oxidation. The above results prove CB for MB application can be reversed by electrochemical reoxidation through C=O moiety recovery or potential activation and CB’s capacity recovery is decided by electrochemical parameters.
Compared to direct electrochemical regeneration of CB, another desirable strategy is exposing CB to some oxidant. Here in our study nitrate was chose as the potential activator for CB’s electron-accepting capability. As shown in Fig. 5, nitrate was slightly removed (removal efficiency ranging between 6.8% and 11.0%) within the first 8 h, without nitrite and ammonia accumulation throughout the whole reaction process of 88 h when no autotrophic nitrate-reduction bacteria (ANRB) were inoculated in the CB control systems, indicating limited sorption of nitrate by bare CB electrode in this study. In ANBR-control, nitrate was removed instantly but only to a limited extent (23.6%), with slight nitrite and ammonium accumulation detected (Fig. S11). This indicated that some nitrate could be reduced by ANBR deriving electrons from itself, the phenomenon of which could be clarified by the knowledge that many species store electrons in their periplasmic and outer-surface cytochromes38, 39. As ANRB were combined with charged CB, nitrate was constantly removed over 88 h with impressive accumulation of ammonia and gradual depletion of nitrite after its initial peak during the first 8 h of the experiment (Fig. 5a–d). These results suggested that electron-saturated solid-state CB electrodes can serve as electron donors for microbial nitrate reduction and microbial-catalyzed nitrate activation can meet the potential criterion for the recovery of CB’s electron-capturing ability.
Moreover, nitrate experienced different reduction kinetics when CBs with different pre-treatments were used as electron donors. It indicated that the nitrate removal rate and amount depended on the capacities of CBs, i.e., unsintered > sintered under 70% O2 and 30% N2 > sintered under 30% O2 and 70% N2 > sintered under 100% N2 (Fig. 5). Unsintered CB exhibited the fastest nitrate removal rate and the highest removal efficiency of 76.2% in 88 h (Fig. 5a), while the 100% N2 sintered CB exhibited the slowest removal rate and the lowest removal efficiency of 45.4% (Fig. 5d).
The ability of CB to act as an electron sink could be recovered by donating electrons to nitrate (Fig. S12). After nitrate reduction, CB electrodes were reinstalled to MBs for measurements. The current curves based on different CBs, regardless of pre-treatments, closely matched those of their initial charging curves (Fig. S12), and their capacities were almost recovered (Table S4). Meanwhile, an evaluation of capacity balance was conducted to reveal the fate of electrons donated by CBs (the specific calculation of capacity balance can be found in Supplementary Information). According to the observed ammonium formation and nitrate loss, around 120.0% capacity was calculated to have participated in nitrate reduction for all CB electrodes (Table S4). This slight exceeding of the 100% capacity contribution of CB to nitrate reduction was probably attributable to nitrate’s potential reduction flux into other products such as nitrogen monoxide or nitric oxide, both of which experience less electron transfer per unit nitrogen reduction. Although this topic deserves further study, these figures strongly hint that the solid-state CB electrodes can be fully regenerated by donating electrons to nitrate reduction through a favorable microbial catalysis process.
Compared with the regeneration method of electrochemical oxidation, the strategy based on transferring electrons to oxidant seems to be more favorable, as no extra electrical energy would be consumed by this spontaneous redox reaction. Moreover, compared to oxygen being regarded as regeneration activator, feasibility of recovery by nitrate reduction yields more significant applied engineering implications. By a spontaneous microbial respiration process, ideally, electrons can be harvested from wastewater2, 40 in MBs and stored in CBs, through which bioavailable electrons become mobile. In the long run, these mobile ‘electron storerooms’ can then be applied to wider ex-situ remediation of pollutants (such as the reduction of heavy metal Cr(VI)41, dechlorination of chloride compounds42) in sediments or wastewater plants. Moreover, as this step happens outside MBs, parameters like temperature, pressure, and electrolyte composition can be optimized for practical application.
Resilience and Persistence of Chemical Activity of CB Electrode
Lifetime in terms of resilience and persistence is another important concern for the cathode of MB for its practical application. Current curves showed that the electron accepting capability of CB could be reversed after reduplicated charge–discharge cycles (Fig. S13), indicating a good resilience and persistence of its chemical activity. Further calculations revealed that the capacities of all CB electrodes were fully preserved during the initial 250 cycles (Fig. 6). CB electrodes experienced a constant decrease in capacity after 2000 cycles, with reductions of 32.9%, 32.7%, 30.8%, and 21.8% for unsintered CB, CB sintered under 70% O2 and 30% N2, CB sintered under 30% O2 and 70% N2, and CB sintered under 100% N2, respectively (Fig. 6). Given the potential activation of capacity by electrochemical processes indicated by the results above, this fall in capacity was probably caused by the annihilation of some active surface moieties. Considering the easy accessibility as well as low-price of carbon materials, these capacity loss is relatively acceptable from a practical application consideration.
Conclusions
The results of this work confirm the chemical activity of CB and prove its potential as a promising alternative by its low-cost, easy-regeneration and resilience for the solid-state cathode in MBs. CB is potential-favorable to derive electrons from biodegradable organics by microbial extraction. The coincidence between the capacity of CB cathode and its abundance of C=O moiety indicates CB’s role as electron sink derived from redox-active C=O functionality. Reduced BC in the cathode of MBs can be recovered by electrochemical reoxidation through a reversible C=O moiety shift. Besides, this study suggests CB cathode of MBs can also be regenerated by a more desirable method through ex-situ microbial-catalyzed redox reaction to release electrons to nitrate.
Methods
Chemicals and Materials
A finely powdered highly conductive carbon black, Cabot VXC 72 R CB (surface area: 254 m2/g, average primary particle size: 30 nm, DBP-absorption: 192 cc/100 g, density: 96.1 g/L) was purchased from Cabot China Inc. and used as received. PTFE suspension (60 wt%) was received from Hesen Electrical Co., Ltd, Shanghai, China. All other chemicals were of analytical reagent grade and obtained from Changqing Chemical Co., Ltd, Hangzhou, China.
Preparation of CB electrodes
The preparation of the CB electrodes was conducted according to a method modified from a previous report12 (briefly described in Fig. S14): First, 40 wt% of CB was dispersed into 20 times the weight of ethanol in a beaker and ultrasonically agitated for 30 min at 30 °C. Next, 60 wt% PTFE suspension was dripped into the blend slowly and the mixture was ultrasonicated for another 30 min to fully disperse the carbon black and PTFE particles. The blend was then stirred and dried in an 80 °C bath to produce a dough-like paste. The paste was then molded and rolled into an even sheet electrode (circular in shape with a diameter of 3 cm and thickness of 2 mm). Afterwards, electrodes were treated with different methods including naturally dried at room temperature or sintered at 340 °C for 30 min under different atmospheres: 100% N2, N2 and O2 mixed at the volume ration of 3:7 and 7:3 respectively. The sintering was carried out in a sealed tubular furnace (GWL-1400xa, Juxing Ltd., Luoyang, China) under a constant gas flow rate of 400 mL/min. The purpose of these diverse treatments is to form CB with different moiety characters to identify the relation between functionality and electron-capturing capability.
Redox Characterizations of CB electrodes
Linear sweep voltammetry (LSV) and cyclic voltammetry (CV) were used to investigate the electrochemical redox properties of CB electrodes with the electrochemical workstation (Biologic VSP, Claix, France). Both measurements were conducted in a three-electrode configuration, with a newly manufactured or totally charged CB electrode as the working electrode, a platinum electrode as the auxiliary electrode, and an Ag/AgCl reference electrode. For LSVs, the potential was scanned from the open circuit potential to −1.0 V (vs Ag/AgCl electrode) at a scan rate of 1.0 mV s−1. CVs were conducted at the potential window from −1.5 V to 1.5 V and at the scan rate of 1.0 mV s−1.
Electrochemical measurements in MBs
The configuration of MB was as described previously43. The detailed configuration and schematic diagram of the MB were presented in the Supplementary Information (Fig. S2). Anode electrodes were primarily pre-colonized for 15 d in a high-throughput bioelectrochemical system (BES) reactor44, in which several anodes shared the same cathode and the reference electrode. A mixture of modified M9 medium (NH4Cl, 0.1 g/L, NaCl, 0.5 g/L, KH2PO4, 4.4 g/L, K2HPO4, 3.4 g/L, MgSO4, 0.1 g/L, NaHCO3, 2 g/L) with trace elements and 1.5 g/L sodium acetate was used as the anodic medium45. Meanwhile, an exoelectrogens, i.e., Geobacter, pre-enriched in our laboratory43, was inoculated as the inoculum. M9 medium with 10 g/L potassium ferricyanide was used as the cathodic electrolyte. Once the anodes had reached their stable current intensities, they were reinstalled to the MBs described above.
For measurements, M9 with 1.5 g/L sodium acetate was used as the anodic electrolyte, while M9 solution without potassium ferricyanide was used as the cathode electrolyte, with the fabricated CB cathodes as potentially the sole electron acceptors. MBs were operated under anaerobic conditions without the presence of oxygen as potential electron acceptor. An external resistance (1 ohm) was applied to connect the anode and cathode for current collection using a data acquisition system (34970 A, Agilent, America). The electron capacity of the CB samples was calculated by integrating current profile according to the formula: C = \({\int }_{0}^{T}{Itdt}\), where I is the current collected and T is the time when MBs were approaching current values of zero.
Regeneration of CB electrodes by electrochemical oxidation
Once the CB electrodes were totally “charged” (fully saturated with electrons from the organics and approaching no current output) in MBs, their regenerations were tested by discharging in a three-electrode configuration46, with platinum auxiliary electrode and Ag/AgCl reference electrode using an electrochemical workstation mentioned above. The discharging process was conducted in modified M9 solution for 1 h at a constant current of 0.1 mA, 0.5 mA, and 1.0 mA, separately. Then discharged CB electrodes were re-migrated to MBs to evaluate their electron-capture abilities.
Regeneration of CB electrodes by exposure to nitrate
Once the CB electrodes had been fully “charged” in MBs, they were anaerobically transferred to a 100 mL anaerobic culture bottle with a working volume of 50 mL. M9 without NH4Cl was used as the medium, and 1.1 mM NaNO3 was added as the potential electron acceptor. The medium was inoculated with pre-enriched autotrophic nitrate-reduction sludge (specific enrichment method and functional effectiveness seen in Supplementary Information) at a mixed liquid sludge solids concentration of 300 mg/L for autotrophic nitrate reduction with the charged BC electrode as the sole electron donor. The inoculated medium was first aerated in a mixture of N2 and CO2 gas (v/v = 80/20) for 30 min and then cultured anaerobically at 30 °C in oven oscillator (SKY-2102C, Shukun, Ltd., Shanghai, China) operated at 160 rpm. As soon as the reduction reaction ceased, the discharged electrodes were reinstalled to MBs to study the recovery of their electron-capture property.
Resilience and persistence tests
The resilience and persistence of the chemical activity of the CB electrodes were tested by evaluating their inherent electron capacities after repeated charging–discharging processes, to show if CB electrodes are robust for long-time operation. The charging-discharging cycles were performed using the three-electrode configuration as for the reversibility tests. The galvanostatic cycling with potential limitation (GCPL) module of the electrochemical workstation (Biologic VSP, Claix, France) was used to achieve 250, 500, 1000, and 2000 charge–discharge cycles, each with a stable potential as terminal discharging and charging platform. At the end of the cycling process, the CB electrodes were reinstalled to MBs and then tested.
Fourier transform infrared spectroscopy (FTIR)
FTIR analysis was performed on a Fourier transform infrared spectrometer (Vertex 70, Bruker, Germany) in the frequency range 4500–500 cm−1.
X-ray Photoelectron Spectroscopy (XPS)
XPS spectra were collected using an EscaLab 250Xi spectrometer with a monochromated Al Kα source (Thermo, UK). Spectra calibrated on the 538.1 (O1s) and 296.1 (C1s) eV peaks were analyzed using XPSPEAK (version 4.1) software.
References
Logan, B. E. & Regan, J. M. Microbial fuel cells–challenges and applications. Environ. Sci. Technol. 40, 5172–5180 (2006).
Logan, B. E. & Rabaey, K. Conversion of wastes into bioelectricity and chemicals by using microbial electrochemical technologies. Science 337, 686–690 (2012).
Liu, H. & Logan, B. E. Electricity generation using an air-cathode single chamber microbial fuel. Environ. Sci. Technol. 38, 4040–4046 (2004).
Erable, B., Feron, D. & Bergel, A. Microbial catalysis of the oxygen reduction reaction for microbial fuel cells: a review. ChemSusChem 5, 975–987 (2012).
Zhang, X. Y., Cheng, S. A., Huang, X. & Logan, B. E. The use of nylon and glass fiber filter separators with different pore sizes in air-cathode single-chamber microbial fuel cells. Energy Environ. Sci. 3, 659–664 (2010).
Xie, X. et al. Microbial battery for efficient energy recovery. PNAS 110, 15925–15930 (2013).
Xie, X. et al. Use of low cost and easily regenerated prussian blue cathodes for efficient electrical energy recovery in a microbial battery. Energy Environ. Sci. 8, 546–551 (2015).
Xie, X., Criddle, C. & Cui, Y. Design and fabrication of bioelectrodes for microbial bioelectrochemical systems. Energy Environ. Sci. 8, 94–113 (2015).
Zhou, M. H., Chi, M. L., Luo, J. M., He, H. H. & Jin, T. An overview of electrode materials in microbial fuel cells. J. Power Sources 196, 4427–4435 (2010).
Zhang, F., Saito, T., Cheng, S., Hickner, M. A. & Logan, B. E. Microbial fuel cell cathodes with poly (dimethylsiloxane) diffusion layers constructed around stainless steel mesh current collectors. Environ. Sci. Technol. 44, 1490–1495 (2010).
Cheng, S. A., Liu, H. & Logan, B. E. Increased performance of single-chamber microbial fuel cells using an improved cathode structure. Electrochem. Commun. 8, 489–494 (2006).
Dong, H., Yu, H. B., Wang, X., Zhou, Q. X. & Feng, J. L. A novel structure of scalable air-cathode without Nafion and Pt by rolling activated carbon and PTFE as catalyst layer in microbial fuel cells. Water Res. 4, 5777–5787 (2012).
Zimmerman, J. R., Ghosh, U., Millward, R. N., Bridges, T. S. & Luthy, R. G. Addition of carbon sorbents to reduce PCB and PAH bioavailability in marine sediments: physicochemical tests. Environ. Sci. Technol. 38, 5458–5460 (2004).
Cho, Y. M. et al. Field application of activated carbon amendment for in situ stabilization of polychlorinated biphenyls in marine sediment. Environ. Sci. Technol. 43, 3815–3823 (2009).
Tan, X. F. et al. Biochar-based nano-composites for the decontamination of wastewater: A review. Bioresource Technol. 212, 318–333 (2016).
Xu, W., Dana, K. E. & Mitch, W. A. Black carbon-mediated destruction of nitroglycerin and RDX by hydrogen sulfide. Environ. Sci. Technol. 44, 6409–6415 (2010).
Zee, F. P. V. D., Bisschops, I. A. E., Lettinga, J. A. & Field, J. A. Activated carbon as an electron acceptor and redox mediator during the anaerobic biotransformation of azo dyes. Environ. Sci. Technol. 37, 402–408 (2003).
Oh, S. Y. & Chiu, P. C. Graphite- and soot-mediated reduction of 2,4-dinitrotoluene and hexahydro-1,3,5-trinitro-1,3,5-triazine. Environ. Sci. Technol. 43, 6983–6988 (2009).
Robles, A. C., Martinez, E., Frontana, C. & Gutierrez, L. G. Development of an activated carbon-packed microbial bioelectrochemical system for azo dye degradation. Bioresource Technol. 127, 37–43 (2013).
Dong, H., Yu, H., Yu, H. B., Gao, N. S. J. & Wang, X. Enhanced performance of activated carbon-polytetrafluoroethylene air-cathode by avoidance of sintering on catalyst layer in microbial fuel cells. J. Power Sources 232, 132–138 (2013).
Huggins, T., Wang, H., Kearns, J., Jenkins, P. & Ren, Z. J. Biochar as a sustainable electrode material for electricity production in microbial fuel cells. Bioresource Technol. 157, 114–119 (2014).
Liu, F. H. et al. Promoting direct interspecies electron transfer with activated carbon. Energy Environ. Sci. 5, 8982–8989 (2012).
Zhang, F., Pant, D. & Logan, B. E. Long-term performance of activated carbon air cathodes with different diffusion layer porosities in microbial fuel cells. Biosens. Bioelectron. 30, 49–55 (2011).
Bustin, R. & Guo, Y. Abrupt changes (jumps) in reflectance values and chemical compositions of artificial charcoals and inertinite in coals. Int. J. Coal Geol. 38, 237 (1999).
Haberhauer, G., Rafferty, B., Strebl, F. & Gerzabek, M. Comparison of the composition of forest soil litter derived from three different sites at various decompositional stages using FTIR spectroscopy. Geoderma 83, 331–342 (1998).
Chen, B., Zhou, D. & Zhu, L. Transitional adsorption and partition of nonpolar and polar aromatic contaminants by biochars of pine needles with different pyrolytic temperatures. Environ. Sci. Technol. 42, 5137–5143 (2008).
Scott, D. T., McKnight, D. M., Blunt-Harris, E. L., Kolesar, S. E. & Lovley, D. R. Quinone moieties act as electron acceptors in the reduction of humic substances by humics-reducing microorganisms. Environ. Sci. Technol. 32, 2984–2989 (1998).
Cory, R. M. & McKnight, D. M. Fluorescence spectroscopy reveals ubiquitous presence of oxidized and reduced quinones in dissolved organic matter. Environ. Sci. Technol. 39, 8142–8149 (2005).
Zielke, U., Huttinger, K. J. & Hoffman, W. P. Surface-oxidized carbon fibers: I. Surface structure and chemistry. Carbon 34, 983–998 (1996).
Valdes, H., Sanchez-Polo, M., Rivera-Utrilla, J. & Zaror, C. A. Effect of ozone treatment on surface properties of activated carbon. Langmuir 18, 2111–2116 (2002).
Frackowiak, E. & Beguinb, F. Carbon materials for the electrochemical storage of energy in capacitors. Carbon 39, 937–950 (2011).
Yan, J. et al. Template-assisted low temperature synthesis of functionalized graphene for ultrahigh volumetric performance supercapacitors. Acsnano 8, 4720–4729 (2014).
Nitta, N. et al. Li-ion battery materials: present and future. Materialstoday 8, 252–264 (2015).
Lee, D. U. et al. Self-assembled NiO/Ni(OH)2 Nanoflakes as Active Material for High Power and High Energy Hybrid Rechargeable Battery. Nano Lett. 16, 1794–1802 (2016).
Miranda-Hernández, M., AyalaMarina, J. & Rincón, E. Effect of surface structure on the charge storage capacity of carbon black electrodes. J. Solid State Electrochem. 7, 271–276 (2003).
Wu, X. L. et al. Functionalized three-dimensional graphene networks for high performance supercapacitors. Carbon 92, 26–30 (2015).
Rosolen, J. M. et al. Carbon nanotube felt composite electrodes without polymer binders. J. Power Sources 162, 620–628 (2006).
Lovley, D. R. et al. Geobacter: the microbe electric’s physiology, ecology, and practical applications. Adv. Microb. Physiol. 59, 1–100 (2011).
Icopini, G. A., Lack, J. G., Hersman, L. E., Neu, M. P. & Boukhalfa, H. Plutonium(V/VI) reduction by the metal-reducing bacteria Geobacter metallireducens GS-15 and Shewanella oneidensis MR-1. Appl. Environ. Microbiol. 75, 3641–3647 (2009).
Pant, D. et al. Bioelectrochemical systems (BES) for sustainable energy production and product recovery from organic wastes and industrial wastewaters. RSC Advances 2, 1248–1263 (2012).
Tandukar, M., Huber, S. J., Onodera, T. & Pavlostathis, S. G. Biological chromium (VI) reduction in the cathode of a microbial fuel cell. Environ. Sci. Technol. 43, 8159–8165 (2009).
Strycharz, S. M. et al. Reductive dechlorination of 2-chlorophenol by Anaeromyxobacter dehalogenans with an electrode serving as the electron donor. Environ. Microbiol. Rep. 2, 289–298 (2010).
Liang, Y. X. et al. Metal-based anode for high performance bioelectrochemical systems through photo-electrochemical interaction. J. Power Sources 324, 26–32 (2016).
Guo, K. et al. Effects of surface charge and hydrophobicity on anodic biofilm formation, community composition, and current generation in boelectrochemical systems. Environ. Sci. Technol. 47, 7563–7570 (2013).
Rabaey, K. et al. Microbial ecology meets electrochemistry: electricity-driven and driving communities. ISME J. 1, 9–18 (2007).
Stoller, M. D. & Ruoff, R. S. Review of Best practice methods for determining an electrode material’s performance for ultracapacitors. Energy Environ. Sci. 3, 1294–1301 (2010).
Acknowledgements
We thank the National Natural Science Foundation of China (51478431) and Science and Technology Planning Project of Zhejiang Province (2015C33025) for funding this work. We also thank the anonymous reviewers for their insightful comments.
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X.Z., K.G., D.S., H.F. and M.W. conceived the study. X.Z. conducted and leaded the whole experiments. Y.J. performed the electrochemical characterization; Y.L. helped the analysis of XPS data; M.Z. enriched the autotrophic nitrate-reduction bacteria and conducted part of nitrate reduction tests. X.Z., K.G., D.S., H.F., M.W. and Y.Z. wrote the manuscript in consultation with all other authors.
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Zhang, X., Guo, K., Shen, D. et al. Carbon black as an alternative cathode material for electrical energy recovery and transfer in a microbial battery. Sci Rep 7, 6981 (2017). https://doi.org/10.1038/s41598-017-07174-z
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DOI: https://doi.org/10.1038/s41598-017-07174-z
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