Abstract
We present a correlation for determining the power density of microbial fuel cells based on dimensional analysis. Important operational, design and biological parameters are non-dimensionalized using a selection of scaling variables. Experimental data from various microbial fuel cell studies operating over a wide range of system parameters are analyzed to attest accuracy of the model in predicting power output. The correlation predicts nonlinear dependencies between power density, substrate concentration, solution conductivity, external resistance, and electrode spacing. The straightforward applicability without the need for any significant computational resources, while preserving good level of accuracy; makes this correlation useful in focusing the experimental effort for the design and optimization of microbial fuel cells.
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Introduction
Current and future risks of climate change have led to a surge of research on innovative technologies that can help reduce our carbon footprint1. Microbial fuel cell (MFC) is one such technology, that has the potential to reduce the extensive energy requirement of wastewater treatment plants by exploiting the chemical energy of organic matter present in the wastewater2,3. MFCs achieve this by employing electroactive bacteria that are not only capable of catalyzing the oxidation of organic matter but can also transfer the electrons released in this process to a solid electron acceptor, electrode (anode) in this case.
Extensive research on material development (electrodes, membranes, catalysts, etc.) and further understanding of the biofilm dynamics (extracellular electron transfer, pure/mixed culture microbial communities, interface characteristics, etc.) has led to great progress in reducing the cost and improving the power output of MFCs4,5,6. However despite the advancements, making MFCs an energy-positive system still remains a technological bottleneck which is preventing its practical application in wastewater treatment or power generation7,8.
One of the reasons for this snag is the lack of means for quick translation of gains in one field across the whole system, largely due to poor understanding of the large number of entwined parameters that influence MFC performance. Experimental studies have shown that power output is a function of several biological (bacterial growth kinetics, source of bacteria, electron transfer mechanism, etc.), design (electrode spacing, architecture, electrode material & thickness, membrane characteristics, etc.) and operational (external resistance, pH, temperature, feed composition & concentration, flow rate etc.) parameters9,10. Most of these parameters are linearly or non-linearly interconnected and thus gains due to improvement in one variable cannot be smoothly extrapolated9. While more research on individual aspects such as electrode materials, specific microbial communities, MFC architecture, etc. is certainly needed, it is also essential to quickly quantify the gains achieved in overall power density considering any new advancement. Best way to assess the maximum improvement in power density in all the different scenarios (with different combinations of the system variables to identify the optimum gain) is through experimental studies. However testing each scenario through experiments is expensive, both in terms of time as well as resources11,12. An alternative is computational modeling. In recent years, lot of progress has been made in the development of comprehensive mathematical models that provide good approximation of the power output of MFCs13,14. However the more detailed computational models which provide good performance prediction also require extensive computational resources13,15. Performing these mathematical simulations also usually requires access to at least one type of ODE/PDE solver and some level of mathematical expertise to run the simulation and understand the output.
A simple analytical correlation linking the different system parameters to power density could constitute a helpful tool in this aspect. However given the large number of parameters and their complex interdependence, it is difficult to obtain a direct correlation with a set of important parameters. Some studies in the past have provided scaling relationships or correlations between individual parameters or with a small subset16,17,18,19,20,21. While such expressions are useful, they are often limited to the particular experimental setup and operating conditions, as they are focused on just 1 or 2 parameters and ignore the interdependencies with others. In this paper we resolve this issue using dimensional analysis22,23,24.
Methodology
Based on the extensive literature on MFCs from both experimental and computational studies, some of the most important parameters that influence power production are identified. These include, COD concentration, wastewater conductivity, surface area of electrodes, electrode spacing, external resistance, substrate consumption rate, half saturation coefficient, and half maximum rate potential9,13,25. Table 1 lists parameters identified as essential for the quantification of power density of MFCs.
We have total eight independent variables and one dependent variable (P). Following Buckingham-π method, and selecting four repeating variables (Ks, d, qmax, and Eka) for the four base dimensions (M, L, T, A), the number of experimental variables to be correlated can be reduced considering the following five dimensionless parameters:
In accordance with the Buckingham-π theorem, these dimensionless groups are related by a general function equation:
Several experimental studies have found that power density increases with increase in conductivity and COD concentration and in both cases it reaches a plateau following a Monod-type kinetics. Also, power density has been shown to be directly proportional to surface area of anode and inversely proportional to external resistance9,13. Equation 6 can therefore be rearranged in the following form:
where, C1, C2, C3, α1, α2, α3, and α4 are constants.
These dimensionless groups reflect the biological, operational, design and electrochemical parameters of MFCs. Equation 7 can be used to describe the dependence of power density on the system parameters once the different C and α values are quantified.
In this work, the constant values are determined by fitting Eq. 7 on experimental estimates of Πp, Πr, Πσ, Πs and ΠA using a nonlinear error minimization routine. Experimental data was obtained from literature of MFC studies in the last 15 years. To determine the dimensionless groups, we needed the values of all 9 variables described in Table 1, from each study. And while there are a large number of experimental studies on MFCs, very few provide the full set of experimental conditions. We found 38 data sets from total 10 studies16,18,26,27,28,29,30,31,32,33, from where we could obtain most of the required variables. These included both single and double chamber MFCs, some using acetate or glucose as the substrate while others using real wastewater from brewery or domestic use. For some data sets, the biological variables such as qmax and Ks were not provided in the study. In such cases, we used the following default values as shown in Table 2, in accordance with other studies where similar experimental conditions were used.
Half maximum rate potential or Eka is another variable that is difficult to determine. It depends on the specific bacterial communities present in the biofilm as well on the substrate (COD) in the wastewater. Since many experimental studies did not report on the particular Eka value, this variable was used as a fitting parameter varying between 0.1 to 0.3 depending on the specific biomass and substrate feed25.
Results and Discussion
Substituting all the experimental estimates of Πp, Πr, Πσ, Πs, & ΠA, and performing nonlinear regression analysis, allowed us to establish the correlation given by Eq. 8.
Figure 1 compares the experimental data for power density and the theoretical values as predicted using Eq. 8, for different data sets with varying COD concentration, external resistance, electrode spacing, wastewater conductivity and projected surface area of electrodes. As can be seen from Fig. 1, the predicted power density values obtained from the proposed correlation in Eq. 8, closely match the experimental data and most of the points are within a ±10% deviation band, which is within the magnitude of the experimental error generally accepted for power density measurements in MFCs11,34.
Also, it can seen from Fig. 1, the correlation predictions successfully match the experimental power densities for over three orders of magnitude, from 0.0025 W m−2 18 to over 2.5 W m−2 27. The statistical analysis of all the experimental and calculated set of data, give a correlation coefficient close to 0.91, which reconfirm that the model equation [Eq. (8)] provides a fairly good representation of experimental data.
Considering the complexity of the process and the number of phenomena involved in MFC operation, the proposed correlation provides a satisfactory approximation of the experimental data. This simple, yet robust correlation can be used to quickly quantify the maximum power density that can be obtained when introducing an improvement/change in any of the 8 important variables as presented in Table 1. This will not only save material resources and time by narrowing down the specific experiments that need to be performed for assessing maximum power density gains, but also help in deriving the conditions required for scaling up, based on similarity theory35. It should be noted that the proposed correlation is not predicting the scaling of power density individually with any of the variables used in Table 1, but only as a set of dimensionless complexes. Given the modified Monod-type kinetics included for conductivity and COD concentration, it is difficult to simplify Eq. 8 by collating the exponents and obtain the individual scaling with different variables. Thus the exponents of Πσ or Πs do not represent the scaling coefficients for conductivity or COD concentration.
The proposed correlation can be improved by incorporating the active specific surface area (As) in place of projected surface area of anode (A). As provides the true area available for the growth of biofilm and the total reaction area accessible for the substrate consumption, particularly in case of porous electrodes. However in most cases, the accurate value of As is not known, and even when the value is provided the final surface area available for substrate oxidation is a function of the porosity of the electrodes, which limits the use of As in a generalized correlation as proposed in Eq. 8. Thus the correlation in the current form is not valid for MFCs using graphite fiber brush anodes where the reaction surface area is vastly different from projected surface area. Equation 8 may also need to be revised to consider special cases such as effect of metal doping of electrodes36 or micro-structured anode obtained by surface wrinkling37, that change multiple properties of the electrodes along with its topography and something that has not been completely characterized yet.
Also, since most of the experimental studies on MFCs have reported data based on a batch or fed-batch system, an important variable, the wastewater flow rate (Q) in continuous MFC systems, which has been shown to influence power production has not been included in the current analysis. On availability of more organized data sets of MFCs operated in continuous mode, a new dimensionless number (ΠQ) can be obtained and added to a revised form of Eq. 8.
Conclusion
For the first time, a robust mathematical correlation has been proposed to calculate power density of microbial fuel cells. Based on dimensional analysis approach, this correlation accounts for eight important system variables and provides an expression for dimensionless power density as a function of dimensionless external resistance, COD concentration, solution conductivity and projected surface area of anode. It captures the functional dependencies between power density and the important system parameters. The final scaling presented in the analysis is validated against 38 experimental data sets covering a broad range of system parameters and about 3 orders of magnitude of power density. The proposed correlation can be readily used by MFC researchers for preliminary power density calculations and optimizing the resources for future development of this technology.
References
Bosetti, V., Carraro, C., Massetti, E. & Tavoni, M. Climate Change Mitigation, Technological Innovation and Adaptation: A New Perspective on Climate Policy. (Edward Elgar Publishing, 2014).
Gao, H., Scherson, Y. D. & Wells, G. F. Towards energy neutral wastewater treatment: methodology and state of the art. Environ. Sci. Processes Impacts 16(6), 1223–1246 (2014).
Li, W.-W., Yu, H.-Q. & He, Z. Towards sustainable wastewater treatment by using microbial fuel cells-centered technologies. Energy Environ. Sci. 7(3), 911–924 (2014).
He, L. et al. Advances in microbial fuel cells for wastewater treatment. Renewable Sustainable Energy Rev. 71, 388–403 (2017).
Xie, X., Criddle, C. & Cui, Y. Design and fabrication of bioelectrodes for microbial bioelectrochemical systems. Energy Environ. Sci. 8(12), 3418–3441 (2015).
Rinaldi, A. et al. Engineering materials and biology to boost performance of microbial fuel cells: a critical review. Energy Environ. Sci. 1(4), 417–429 (2008).
Do, M. H. et al. Challenges in the application of microbial fuel cells to wastewater treatment and energy production: a mini review. Sci. Total Environ. 639, 910–920 (2018).
Slate, A. J., Whitehead, K. A., Brownson, D. A. C. & Banks, C. E. Microbial fuel cells: An overview of current technology. Renewable Sustainable Energy Rev. 101, 60–81 (2019).
Oliveira, V. B., Simões, M., Melo, L. F. & Pinto, A. M. F. R. Overview on the developments of microbial fuel cells. Biochem. Eng. J. 73, 53–64 (2013).
Gude, V. G. Wastewater treatment in microbial fuel cells–an overview. J. Cleaner Prod. 122, 287–307 (2016).
Sivasankar, V., Mylsamy, P. & Omine, K. Microbial Fuel Cell Technology for Bioelectricity. (Springer, 2018).
Mateo, S., Cañizares, P., Fernandez-Morales, F. J. & Rodrigo, M. A. A critical view of microbial fuel cells: What is the next stage? ChemSusChem 11, 4183–4192 (2018).
Gadkari, S., Gu, S. & Sadhukhan, J. Towards automated design of bioelectrochemical systems: A comprehensive review of mathematical models. Chem. Eng. J. 343, 303–316 (2018).
Xia, C., Zhang, D., Pedrycz, W., Zhu, Y. & Guo, Y. Models for microbial fuel cells: A critical review. J. Power Sources 373, 119–131 (2018).
Picioreanu, C., Head, I., Katuri, K. P., van Loosdrecht, M. C. M. & Scott, K. A computational model for biofilm-based microbial fuel cells. Water Res. 41(13), 2921–2940 (2007).
Feng, Y., Wang, X., Logan, B. E. & Lee, H. Brewery wastewater treatment using air-cathode microbial fuel cells. Appl. Microbiol. Biotechnol. 78(5), 873–880 (2008).
Sang-Eun, O. & Logan, B. E. Proton exchange membrane and electrode surface areas as factors that affect power generation in microbial fuel cells. Appl. Microbiol. Biotechnol. 70(2), 162–169 (2006).
Lee, C.-Y. & Huang, Y.-N. The effects of electrode spacing on the performance of microbial fuel cells under different substrate concentrations. Water Science and Technology 68(9), 2028–2034 (2013).
Malvankar, N. S., Tuominen, M. T. & Lovley, D. R. Biofilm conductivity is a decisive variable for high-current-density geobacter sulfurreducens microbial fuel cells. Energy Environ. Sci. 5(2), 5790–5797 (2012).
Salar-García, M. J., de Ramón-Fernández, A., Ortiz-Martínez, V. M., Ruiz-Fernández, D. & Ieropoulos, I. Towards the optimisation of ceramic-based microbial fuel cells: A three-factor threelevel response surface analysis design. Biochem. Eng. J. 144, 119–124 (2019).
de Ramón-Fernández, A., Salar-García, M. J., Ruiz-Fernández, D., Greenman, J. & Ieropoulos, I. Modelling the energy harvesting from ceramic-based microbial fuel cells by using a fuzzy logic approach. Appl. Energy 251, 113321 (2019).
Russo, L., Sorrentino, M., Polverino, P. & Pianese, C. Application of buckingham π theorem for scaling-up oriented fast modelling of proton exchange membrane fuel cell impedance. J. Power Sources 353, 277–286 (2017).
Ortega, J. K. E. Dimensionless numbers for plant biology. Trends Plant Sci. 23(1), 6–9 (2018).
Gadkari, S. B. Scaling analysis for electrospinning. SpringerPlus 3(1), 705 (2014).
Marcus, A. K., Torres, C. I. & Rittmann, B. E. Conduction-based modeling of the biofilm anode of a microbial fuel cell. Biotechnol. Bioeng. 98(6), 1171–1182 (2007).
Ismail, Z. Z. & Jaeel, A. J. Modelling study of an upflow microbial fuel cell catalysed with anaerobic aged sludge. International Journal of Ambient Energy 37(1), 85–93 (2016).
Zhang, L., Zhu, X., Li, J., Liao, Q. & Ye, D. Biofilm formation and electricity generation of a microbial fuel cell started up under different external resistances. J. Power Sources 196(15), 6029–6035 (2011).
Cheng, S., Liu, H. & Logan, B. E. Increased power generation in a continuous flow mfc with advective flow through the porous anode and reduced electrode spacing. Environ. Sci. Technol. 40(7), 2426–2432 (2006).
Min, B., Román, Ó. B. & Angelidaki, I. Importance of temperature and anodic medium composition on microbial fuel cell (mfc) performance. Biotechnol. Lett 30(7), 1213–1218 (2008).
Zhang, B.-G. et al. Factors affecting the performance of microbial fuel cells for sulfide and vanadium (v) treatment. Bioprocess and biosystems engineering 33(2), 187–194 (2010).
Liu, H., Cheng, S. & Logan, B. E. Production of electricity from acetate or butyrate using a single-chamber microbial fuel cell. Environ. Sci. Technol. 39(2), 658–662 (2005).
Hyunsoo, M., Chang, I. S. & Kim, B. H. Continuous electricity production from artificial wastewater using a mediator-less microbial fuel cell. Bioresour. Technol. 97(4), 621–627 (2006).
Subha, C. et al. Bioelectricity generation and effect studies from organic rich chocolaterie wastewater using continuous upflow anaerobic microbial fuel cell. Fuel 251, 224–232 (2019).
Scott, K. & Yu, E. H. Microbial electrochemical and fuel cells: fundamentals and applications. (Woodhead Publishing, 2015).
Zohuri, B. Dimensional analysis and self-similarity methods for engineers and scientists. (Springer, 2015).
Mateo, S., Cañizares, P., Rodrigo, M. A. & Fernandez-Morales, F. J. Driving force of the better performance of metaldoped carbonaceous anodes in microbial fuel cells. Appl. Energy 225, 52–59 (2018).
Amirdehi, M. A., Saem, S., Zarabadi, M. P., Moran-Mirabal, J. M. & Greener, J. Microstructured anodes by surface wrinkling for studies of direct electron transfer biofilms in microbial fuel cells. Adv. Mater. Interfaces 5(13), 1800290 (2018).
Picioreanu, C., van Loosdrecht, M. C. M., Curtis, T. P. & Scott, K. Model based evaluation of the effect of ph and electrode geometry on microbial fuel cell performance. Bioelectrochemistry 78(1), 8–24 (2010).
Alavijeh, M. K., Mardanpour, M. M. & Yaghmaei, S. A generalized model for complex wastewater treatment with simultaneous bioenergy production using the microbial electrochemical cell. Electrochim. Acta 167, 84–96 (2015).
Acknowledgements
The authors would like to acknowledge the financial support by the Natural Environment Research Council (NERC) UK project grant: NE/R013306/1.
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S.G. conceived and designed the study, performed the analysis, and drafted the first version of paper. S.G. and J.S. contributed to the revision process of the manuscript.
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Gadkari, S., Sadhukhan, J. A robust correlation based on dimensional analysis to characterize microbial fuel cells. Sci Rep 10, 8407 (2020). https://doi.org/10.1038/s41598-020-65375-5
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DOI: https://doi.org/10.1038/s41598-020-65375-5
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