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2. Supercapacitive microbial fuel cells

Author

Rahimnejad, M, Poli, F, Soavi, F, Santoro, C, Poli F., Soavi F., Santoro C., Rahimnejad, M, Poli, F, Soavi, F, Santoro, C, Poli F., Soavi F., and Santoro C.

Abstract

The integration of supercapacitive features in microbial fuel cells (MFC) can solve one of the major limitations of this technology, i.e., the low power output. In this chapter, three different strategies to exploit the supercapacitive features of MFCs are reported and discussed: (i) the integration of high specific surface area elements in the electrode to maximize the capacitive response, (ii) the exploitation of a pulsed discharge, and (iii) the decoration of microbial fuel cell electrodes with inorganic pseudocapacitive components.

Published
2023

3. Valorization of the inedible pistachio shells into nanoscale transition metal and nitrogen codoped carbon-based electrocatalysts for hydrogen evolution reaction and oxygen reduction reaction

Author

Muhyuddin, M, Zocche, N, Lorenzi, R, Ferrara, C, Poli, F, Soavi, F, Santoro, C, Muhyuddin M., Zocche N., Lorenzi R., Ferrara C., Poli F., Soavi F., Santoro C., Muhyuddin, M, Zocche, N, Lorenzi, R, Ferrara, C, Poli, F, Soavi, F, Santoro, C, Muhyuddin M., Zocche N., Lorenzi R., Ferrara C., Poli F., Soavi F., and Santoro C.

Abstract

Making a consistency with the objectives of circular economy, herein, waste pistachios shells were utilized for the development of hydrogen evolution reaction (HER) and oxygen reduction reaction (ORR) electrocatalysts which are the key bottleneck in the technological evolution of electrolyzers and fuel cells, respectively. As an alternative to scarce and expensive platinum-group-metal (PGM) electrocatalysts, metal nitrogen carbons (MNCs) are emerging as a promising candidate for both aforementioned electrocatalysis where iron and nickel are the metal of choice for ORR and HER, respectively. Therefore, FeNCs and NiNCs were fabricated utilizing inedible pistachio shells as a low-cost biosource of carbon. The steps involved in the fabrication of electrocatalyst were correlated with electrochemical performance in alkaline media. Encouraging onset potential of ~ 0.88 V vs RHE with a possibility of a 2 + 2 reaction pathway was observed in pyrolyzed and ball-milled FeNC. However, HF etching for template removal slightly affected the kinetics and eventually resulted in a relatively higher yield of peroxide. In parallel, the pyrolyzed NiNC demonstrated a lower HER overpotential of ~ 0.4 V vs RHE at − 10 mA cm−2. Nevertheless, acid washing adversely affected the HER performance and consequently, very high overpotential was witnessed.

Published
2022

4. Lignin-derived bimetallic platinum group metal-free oxygen reduction reaction electrocatalysts for acid and alkaline fuel cells

Author

Muhyuddin, M, Friedman, A, Poli, F, Petri, E, Honig, H, Basile, F, Fasolini, A, Lorenzi, R, Berretti, E, Bellini, M, Lavacchi, A, Elbaz, L, Santoro, C, Soavi, F, Muhyuddin, M, Friedman, A, Poli, F, Petri, E, Honig, H, Basile, F, Fasolini, A, Lorenzi, R, Berretti, E, Bellini, M, Lavacchi, A, Elbaz, L, Santoro, C, and Soavi, F

Abstract

Metal-nitrogen-carbons (M-N-Cs) as a reliable substitution for platinum-group-metals (PGMs) for oxygen reduction reaction (ORR) are emerging candidates to rationalize the technology of fuel cells. The development of M-N-Cs can further be economized by consuming waste biomass as an inexpensive carbon source for the electrocatalyst support. Herein, we report the simple fabrication and in-depth characterization of electrocatalysts using lignin-derived activated char. The activated char (LAC) was functionalized with metal phthalocyanine (FePc and MnPc) via atmosphere-controlled pyrolysis to produce monometallic M-N-Cs (L_Mn and L_Fe) and bimetallic M1-M2-N-Cs (L_FeMn) electrocatalysts. Raman spectroscopy and transmission electron microscopy (TEM) revealed a defect-rich architecture. XPS confirmed the coexistence of various nitrogen-containing active moieties. L_Fe and L_FeMn demonstrated appreciable ORR in both acidic and alkaline conditions whereas L_FeMn helped in restricting the peroxide yield, particularly in alkaline media. L_Fe and L_FeMn demonstrated remarkable onset potential (Eonset) of ∼0.942 V (vs RHE) with an E1/2 of 0.874 V (vs RHE) in 0.1 M KOH. In acid, L_FeMn had an Eonset of 0.817 V (vs RHE) and an E1/2 of ∼0.76 V (vs RHE). Finally, the L_FeMn as a cathode electrocatalyst was integrated and tested in PEMFC and AEMFC. AEMFC demonstrated optimistic performance with a peak power density of 261 mW cm−2 at the current density of ∼577 mA cm−2.

Published
2023

5. Giving New Life to Waste Cigarette Butts: Transformation into Platinum Group Metal-Free Electrocatalysts for Oxygen Reduction Reaction in Acid, Neutral and Alkaline Environment

Author

Testa, D, Zuccante, G, Muhyuddin, M, Landone, R, Scommegna, A, Lorenzi, R, Acciarri, M, Petri, E, Soavi, F, Poggini, L, Capozzoli, L, Lavacchi, A, Lamanna, N, Franzetti, A, Zoia, L, Santoro, C, Testa, Davide, Zuccante, Giovanni, Muhyuddin, Mohsin, Landone, Roberto, Scommegna, Axel, Lorenzi, Roberto, Acciarri, Maurizio, Petri, Elisabetta, Soavi, Francesca, Poggini, Lorenzo, Capozzoli, Laura, Lavacchi, Alessandro, Lamanna, Niccolò, Franzetti, Andrea, Zoia, Luca, Santoro, Carlo, Testa, D, Zuccante, G, Muhyuddin, M, Landone, R, Scommegna, A, Lorenzi, R, Acciarri, M, Petri, E, Soavi, F, Poggini, L, Capozzoli, L, Lavacchi, A, Lamanna, N, Franzetti, A, Zoia, L, Santoro, C, Testa, Davide, Zuccante, Giovanni, Muhyuddin, Mohsin, Landone, Roberto, Scommegna, Axel, Lorenzi, Roberto, Acciarri, Maurizio, Petri, Elisabetta, Soavi, Francesca, Poggini, Lorenzo, Capozzoli, Laura, Lavacchi, Alessandro, Lamanna, Niccolò, Franzetti, Andrea, Zoia, Luca, and Santoro, Carlo

Abstract

Following the core theme of a circular economy, a novel strategy to upcycle cigarette butt waste into platinum group metal (PGM)-free metal nitrogen carbon (M-N-C) electrocatalysts for oxygen reduction reaction (ORR) is presented. The experimental route was composed of (i) the transformation of the powdered cigarette butts into carbonaceous char via pyrolysis at 450 °C, 600 °C, 750 °C and 900 °C, (ii) the porosity activation with KOH and (iii) the functionalization of the activated chars with iron (II) phthalocyanine (FePc). The electrochemical outcomes obtained by the rotating disk electrode (RRDE) technique revealed that the sample pyrolyzed at 450 °C (i.e., cig_450) outperformed the other counterparts with its highest onset (Eon) and half-wave potentials (E1/2) and demonstrated nearly tetra-electronic ORR in acidic, neutral and alkaline electrolytes, all resulting from the optimal surface chemistry and textural properties.

Published
2023

6. Valorization of biodigestor plant waste in electrodes for supercapacitors and microbial fuel cells

Author

Mutuma, B, Sylla, N, Bubu, A, Ndiaye, N, Santoro, C, Brilloni, A, Poli, F, Manyala, N, Soavi, F, Mutuma B. K., Sylla N. F., Bubu A., Ndiaye N. M., Santoro C., Brilloni A., Poli F., Manyala N., Soavi F., Mutuma, B, Sylla, N, Bubu, A, Ndiaye, N, Santoro, C, Brilloni, A, Poli, F, Manyala, N, Soavi, F, Mutuma B. K., Sylla N. F., Bubu A., Ndiaye N. M., Santoro C., Brilloni A., Poli F., Manyala N., and Soavi F.

Abstract

This study aims at demonstrating that wastes from anaerobic biodigester plants can be effectively valorized as functional materials to be implemented in technologies that enable efficient energy management and water treatment, therefore simultaneously addressing the Water-Energy-Waste Nexus challenges. Lignin, the main solid residue of the biodigester plant, has been valorized into activated biochar with a mild activation agent, like KHCO3, to produce electrode of supercapacitors and microbial fuel cells. In addition, the same sludge that is the liquid effluent of the biodigester plant has been exploited as inoculum and electrolyte for the MFC. The lignin-derived carbons obtained at lignin/KHCO3 mass ratios of 1:0.5 (LAC-0.5) and 1:2 (LAC-2) comprised of mesopores and micropores displaying BETs of 1558 m2g−1 and 1879 m2g−1, respectively. LAC-2 carbon exhibited a superior specific capacitance of 114 F g−1 in 2.5 M KNO3 with respect to LAC-0.5. A supercapacitor with LAC-2 electrodes was built displaying specific energy specific power up to 10 Wh kg−1 and 6.9 kW kg−1, respectively. Durability tests showed that the device was able to maintain a capacitance retention of 84.5% after 15,000 charge-discharge cycles. The lignin-derived carbons were also studied as electrocatalysts for ORR in a neutral medium. The LAC-2 showed higher ORR electrocatalytic activity than LAC-0.5. The interconnected porous network and the high surface area made the lignin-derived porous carbons suitable electrode materials for dual applications. The feasibility of the use of LAC 2 carbon incorporated in an air breathing cathode for MFC applications is also reported.

Published
2021

7. Combination of bioelectrochemical systems and electrochemical capacitors: Principles, Analysis and Opportunities

Author

Caizán-Juanarena, L, Borsje, C, Sleutels, T, Yntema, D, Santoro, C, Ieropoulos, I, Soavi, F, ter Heijne, A, Caizán-Juanarena L, Borsje C, Sleutels T, Yntema D, Santoro C, Ieropoulos I, Soavi F, ter Heijne A, Caizán-Juanarena, L, Borsje, C, Sleutels, T, Yntema, D, Santoro, C, Ieropoulos, I, Soavi, F, ter Heijne, A, Caizán-Juanarena L, Borsje C, Sleutels T, Yntema D, Santoro C, Ieropoulos I, Soavi F, and ter Heijne A

Abstract

Bioelectrochemical systems combine electrodes and reactions driven by microorganisms for many different applications. The conversion of organic material in wastewater into electricity occurs in microbial fuel cells (MFCs). The power densities produced by MFCs are still too low for application. One way of increasing their performance is to combine them with electrochemical capacitors, widely used for charge storage purposes. Capacitive MFCs, i.e. the combination of capacitors and MFCs, allow for energy harvesting and storage and have shown to result in improved power densities, which facilitates the up scaling and application of the technology. This manuscript summarizes the state-of-the-art of combining capacitors with MFCs, starting with the theory and working principle of electrochemical capacitors. We address how different electrochemical measurements can be used to determine (bio)electrochemical capacitance and show how the measurement data can be interpreted. In addition, we present examples of the combination of electrochemical capacitors, both internal and external, that have been used to enhance MFC performance. Finally, we discuss the most promising applications and the main existing challenges for capacitive MFCs.

Published
2020

8. Air-breathing cathode self-powered supercapacitive microbial fuel cell with human urine as electrolyte.

Author

Santoro, C, Walter, X, Soavi, F, Greenman, J, Ieropoulos, I, Santoro C, Walter XA, Soavi F, Greenman J, Ieropoulos I, Santoro, C, Walter, X, Soavi, F, Greenman, J, Ieropoulos, I, Santoro C, Walter XA, Soavi F, Greenman J, and Ieropoulos I

Abstract

In this work, a membraneless microbial fuel cell (MFC) with an empty volume of 1.5 mL, fed continuously with hydrolysed urine, was tested in supercapacitive mode (SC-MFC). In order to enhance the power output, a double strategy was used: i) a double cathode was added leading to a decrease in the equivalent series resistance (ESR); ii) the apparent capacitance was boosted up by adding capacitive features on the anode electrode. Galvanostatic (GLV) discharges were performed at different discharge currents. The results showed that both strategies were successful obtaining a maximum power output of 1.59 ± 0.01 mW (1.06 ± 0.01 mW mL−1) at pulse time of 0.01 s and 0.57 ± 0.01 mW (0.38 ± 0.01 mW mL−1) at pulse time of 2 s. The highest energy delivered at ipulse equal to 2 mA was 3.3 ± 0.1 mJ. The best performing SC-MFCs were then connected in series and parallel and tested through GLV discharges. As the power output was similar, the connection in parallel allowed to roughly doubling the current produced. Durability tests over ≈5.6 days showed certain stability despite a light overall decrease.

Published
2020

9. Boosting Microbial Fuel Cell Performance by Combining with an External Supercapacitor: An Electrochemical Study

Author

Poli, F, Seri, J, Santoro, C, Soavi, F, Poli F., Seri J., Santoro C., Soavi F., Poli, F, Seri, J, Santoro, C, Soavi, F, Poli F., Seri J., Santoro C., and Soavi F.

Abstract

Microbial fuel cells (MFCs), despite representing a promising technology, suffer from low power generation that hinders, in most of the cases, their application as power sources. In fact, MFCs are usually coupled with supercapacitors or batteries and these storage units accumulate the energy harvested by MFCs and deliver it on demand. In this work, the electrodes of a MFC are used as electrodes of an internal supercapacitor and discharges and self-recharges are performed and investigated. Discharges between 1.5 mA and 4 mA were presented producing a maximum power of 1.59 mW. Discharges between 1 mA and 100 mA and recharges are systematically studied for three commercial supercapacitors (SCs) with different capacitances of 1 F, 3 F, and 6 F. The MFC was also connected in parallel with external SCs and discharged galvanostatically. The SC was self-recharged by the MFC without any additional external power sources. At lower current pulses, the MFC contributed to the overall capacitance, probably owing to its faradaic component. At higher current pulses, the use of SCs enables the energy to be harvested by MFCs at power levels that could not be achieved with the MFC alone. This study demonstrates that, through the proper connection and operation mode of the MFC and SC, it is possible to improve and maximize the performance of every single unit. Understanding the MFC−SC combination is important for identifying the right practical application for which the combination is suitable.

Published
2020

10. Boosting microbial fuel cells performance by the combination of an external supercapacitor: an electrochemical study

Author

Poli, F, Seri, J, Santoro, C, Soavi, F, Poli F, Seri J, Santoro C, Soavi F, Poli, F, Seri, J, Santoro, C, Soavi, F, Poli F, Seri J, Santoro C, and Soavi F

Abstract

Microbial fuel cells (MFCs), despite representing a promising technology, suffer from low power generation that hinders, in most of the cases, their application as power sources. In fact, MFCs are usually coupled with supercapacitors or batteries and these storage units accumulate the energy harvested by MFCs and deliver it on demand. In this work, the electrodes of a MFC are used as electrodes of an internal supercapacitor and discharges and self-recharges are performed and investigated. Discharges between 1.5 mA and 4 mA were presented produc- ing a maximum power of 1.59 mW. Discharges between 1 mA and 100 mA and recharges are systematically studied for three commercial supercapacitors (SCs) with different capacitances of 1 F, 3 F, and 6 F. The MFC was also connected in parallel with external SCs and discharged galvanostatically. The SC was self- recharged by the MFC without any additional external power sources. At lower current pulses, the MFC contributed to the overall capacitance, probably owing to its faradaic component. At higher current pulses, the use of SCs enables the energy to be harvested by MFCs at power levels that could not be achieved with the MFC alone. This study demonstrates that, through the proper connection and operation mode of the MFC and SC, it is possible to improve and maximize the performance of every single unit. Understanding the MFCSC combination is important for identifying the right practical application for which the combination is suitable.

Published
2020

11. Supercapacitive Operational Mode in Microbial Fuel Cell

Author

Soavi, F, Santoro, C, Soavi F, Santoro C, Soavi, F, Santoro, C, Soavi F, and Santoro C

Abstract

Supercapacitive microbial fuel cells (SC-MFCs) are an emerging and promising field that has captured the attention of scientists in the past few years. This hybridization consists in the integration of supercapacitive features in the MFC electrodes to boost the performance output. The MFC anaerobic and aerobic enviroments induce self-polarization of the electrodes. The electrodes can be discharged galvanostatically and then self-recharged by the biotic/abiotic environments. During the discharge, two main phenomena named electrostatic and faradaic take place but the separation and quantification of the two contributes seems to be challenging. Galvanostatic discharges of SC-MFC produce at least one order of magnitude higher current/power compared with continuous operations, making it promising for pulsed type applications.

Published
2020

13. Iron-based electrocatalysts derived from scrap tires for oxygen reduction reaction: Evolution of synthesis-structure-performance relationship in acidic, neutral and alkaline media

Author

Muhyuddin, M, Testa, D, Lorenzi, R, Vanacore, G, Poli, F, Soavi, F, Specchia, S, Giurlani, W, Innocenti, M, Rosi, L, Santoro, C, Muhyuddin, Mohsin, Testa, Davide, Lorenzi, Roberto, Vanacore, Giovanni Maria, Poli, Federico, Soavi, Francesca, Specchia, Stefania, Giurlani, Walter, Innocenti, Massimo, Rosi, Luca, Santoro, Carlo, Muhyuddin, M, Testa, D, Lorenzi, R, Vanacore, G, Poli, F, Soavi, F, Specchia, S, Giurlani, W, Innocenti, M, Rosi, L, Santoro, C, Muhyuddin, Mohsin, Testa, Davide, Lorenzi, Roberto, Vanacore, Giovanni Maria, Poli, Federico, Soavi, Francesca, Specchia, Stefania, Giurlani, Walter, Innocenti, Massimo, Rosi, Luca, and Santoro, Carlo

Abstract

Mass generation of scrap tires presents a major challenge for environmental safety, however, their upcycling into carbon-based nanomaterials by the virtue of pyrolysis treatments can open up new windows for energy conversion and storage technologies in the context of the circular economy. Herein, we report the synthesis of Fe-N-C oxygen reduction reaction (ORR) electrocatalyst for fuel cell (FC) applications using carbonaceous char derived from scrap tires through microwave-assisted pyrolysis (MAP). The char obtained from MAP was activated with potassium hydroxide and then pyrolyzed at a high temperature to fabricate Fe-N-C after mixing with iron and nitrogen precursors. Finally, the developed Fe-N-C was ball-milled and acid-etched for homogenization and leaching of iron oxide nanoparticles. In this study, structural evaluation during each synthesis step was elucidated and correlated with the ORR activity in all three pHs i.e. acidic, neutral, and alkaline. Moreover, the effect of electrocatalyst loading on ORR kinetics was also analyzed using two different loadings (0.2 and 0.6 mg cm−2) on the rotating ring disk electrode (RRDE). The developed Fe-N-C demonstrated encouraging onset potentials of 0.881, 0.822, and 0.936 V vs RHE in acidic, neutral, and alkaline conditions, respectively. Whereas the ORR activity was slightly reduced after the milling-etching step. Lower peroxide yield together with a tetra-electronic reduction of oxygen was witnessed in acidic and neutral conditions, however, peroxide production was increased in the alkaline medium.

Published
2022

14. Self-stratified and self-powered micro-supercapacitor integrated into a microbial fuel cell operating in human urine

Author

Santoro, C, Walter, X, Soavi, F, Greenman, J, Ieropoulos, I, Santoro C, Walter XA, Soavi F, Greenman J, Ieropoulos I, Santoro, C, Walter, X, Soavi, F, Greenman, J, Ieropoulos, I, Santoro C, Walter XA, Soavi F, Greenman J, and Ieropoulos I

Abstract

A self-stratified microbial fuel cell fed with human urine with a total internal volume of 0.55 ml was investigated as an internal supercapacitor, for the first time. The internal self-stratification allowed the development of two zones within the cell volume. The oxidation reaction occurred on the bottom electrode (anode) and the reduction reaction on the top electrode (cathode). The electrodes were discharged galvanostatically at different currents and the two electrodes were able to recover their initial voltage value due to their red-ox reactions. Anode and cathode apparent capacitance was increased after introducing high surface area activated carbon embedded within the electrodes. Peak power produced was 1.20 ± 0.04 mW (2.19 ± 0.06 mW ml−1) for a pulse time of 0.01 s that decreased to 0.65 ± 0.02 mW (1.18 ± 0.04 mW ml−1) for longer pulse periods (5 s). Durability tests were conducted over 44 h with ≈2600 discharge/recharge cycles. In this relatively long-term test, the equivalent series resistance increased only by 10% and the apparent capacitance decreased by 18%.

Published
2019

15. Chapter 10: Supercapacitors in Bioelectrochemical Systems

Author

Serge Cosnier, Santoro, C, Pankratov, D, Ieropoulos, I, Soavi, F, Santoro C, Pankratov D, Ieropoulos I, Soavi F, Serge Cosnier, Santoro, C, Pankratov, D, Ieropoulos, I, Soavi, F, Santoro C, Pankratov D, Ieropoulos I, and Soavi F

Published
2019

16. Correlating Structure and Properties of Super-Concentrated Electrolyte Solutions: 17O NMR and Electrochemical Characterization

Author

Ruggeri, I, La Monaca, A, De Giorgio, F, Soavi, F, Arbizzani, C, Berbenni, V, Ferrara, C, Mustarelli, P, Ruggeri I., La Monaca A., De Giorgio F., Soavi F., Arbizzani C., Berbenni V., Ferrara C., Mustarelli P., Ruggeri, I, La Monaca, A, De Giorgio, F, Soavi, F, Arbizzani, C, Berbenni, V, Ferrara, C, Mustarelli, P, Ruggeri I., La Monaca A., De Giorgio F., Soavi F., Arbizzani C., Berbenni V., Ferrara C., and Mustarelli P.

Abstract

Super-concentrated electrolyte solutions are of increasing interest for safer and more stable lithium and post-lithium batteries. The combination of 7Li and 17O (at natural abundance) nuclear magnetic resonance (NMR) and electrochemical characterization is proposed here as an effective approach to investigate the Li+ solvation structures and properties of electrolytes featuring tetraethylene glycol dimethyl ether (TEGDME) and lithium-bis(trifluoromethane sulfonyl) imide (LiTFSI). Five different formulations from salt-in-solvent to solvent-in-salt with LiTFSI at different concentrations (0.1 m, 0.5 m, 2 m, 4 m, 5 m) are investigated. The NMR results, also supported by physico-chemical characterizations such as thermal gravimetric analyses, differential scanning calorimetry, specific conductivity and viscosity, give information about the association of Li+ ions with anion and solvent molecules, allowing a deeper knowledge on the relationships among structure and functional properties of super-concentrated solutions.

Published
2019

18. Ceramic Microbial Fuel Cells Stack: power generation in standard and supercapacitive mode

Author

Santoro, C, Flores-Cadengo, C, Soavi, F, Kodali, M, Merino-Jimenez, I, Gajda, I, Greenman, J, Ieropoulos, I, Atanassov, P, Santoro C, Flores-Cadengo C, Soavi F, Kodali M, Merino-Jimenez I, Gajda I, Greenman J, Ieropoulos I, Atanassov P, Santoro, C, Flores-Cadengo, C, Soavi, F, Kodali, M, Merino-Jimenez, I, Gajda, I, Greenman, J, Ieropoulos, I, Atanassov, P, Santoro C, Flores-Cadengo C, Soavi F, Kodali M, Merino-Jimenez I, Gajda I, Greenman J, Ieropoulos I, and Atanassov P

Abstract

In this work, a microbial fuel cell (MFC) stack containing 28 ceramic MFCs was tested in both standard and supercapacitive modes. The MFCs consisted of carbon veil anodes wrapped around the ceramic separator and air-breathing cathodes based on activated carbon catalyst pressed on a stainless steel mesh. The anodes and cathodes were connected in parallel. The electrolytes utilized had different solution conductivities ranging from 2.0 mScm−1 to 40.1 mScm−1, simulating diverse wastewaters. Polarization curves of MFCs showed a general enhancement in performance with the increase of the electrolyte solution conductivity. The maximum stationary power density was 3.2 mW (3.2 Wm−3) at 2.0 mScm−1 that increased to 10.6 mW (10.6 Wm−3) at the highest solution conductivity (40.1 mScm−1). For the first time, MFCs stack with 1 L operating volume was also tested in supercapacitive mode, where full galvanostatic discharges are presented. Also in the latter case, performance once again improved with the increase in solution conductivity. Particularly, the increase in solution conductivity decreased dramatically the ohmic resistance and therefore the time for complete discharge was elongated, with a resultant increase in power. Maximum power achieved varied between 7.6 mW (7.6 Wm−3) at 2.0 mScm−1 and 27.4 mW (27.4 Wm−3) at 40.1 mScm−1.

Published
2018

19. Ceramic Microbial Fuel Cells Stack: Power generation in standard and supercapacitive mode

Author

Santoro C, Flores-Cadengo C, Soavi F, Kodali M, Merino-Jimenez I, Gajda I, Greenman J, Ieropoulos I, Atanassov P, Santoro, Carlo, Flores-Cadengo, Cristina, Soavi, Francesca, Kodali, Mounika, Merino-Jimenez, Irene, Gajda, Iwona, Greenman, John, Ieropoulos, Ioanni, Atanassov, Plamen, Santoro, C, Flores-Cadengo, C, Soavi, F, Kodali, M, Merino-Jimenez, I, Gajda, I, Greenman, J, Ieropoulos, I, and Atanassov, P

Subjects
Microbial Fuel Cell, Supercapacitor, Cell Stack, lcsh:R, lcsh:Medicine, lcsh:Q, lcsh:Science, Article, Microbial Fuel Cell, Discharges, Supercapacitors, large scale
Abstract

In this work, a microbial fuel cell (MFC) stack containing 28 ceramic MFCs was tested in both standard and supercapacitive modes. The MFCs consisted of carbon veil anodes wrapped around the ceramic separator and air-breathing cathodes based on activated carbon catalyst pressed on a stainless steel mesh. The anodes and cathodes were connected in parallel. The electrolytes utilized had different solution conductivities ranging from 2.0 mScm−1 to 40.1 mScm−1, simulating diverse wastewaters. Polarization curves of MFCs showed a general enhancement in performance with the increase of the electrolyte solution conductivity. The maximum stationary power density was 3.2 mW (3.2 Wm−3) at 2.0 mScm−1 that increased to 10.6 mW (10.6 Wm−3) at the highest solution conductivity (40.1 mScm−1). For the first time, MFCs stack with 1 L operating volume was also tested in supercapacitive mode, where full galvanostatic discharges are presented. Also in the latter case, performance once again improved with the increase in solution conductivity. Particularly, the increase in solution conductivity decreased dramatically the ohmic resistance and therefore the time for complete discharge was elongated, with a resultant increase in power. Maximum power achieved varied between 7.6 mW (7.6 Wm−3) at 2.0 mScm−1 and 27.4 mW (27.4 Wm−3) at 40.1 mScm−1.

Published
2018
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20. Three-Dimensional Graphene Nanosheets as Cathode Catalysts in Standard and Supercapacitive Microbial Fuel Cell

Author

Santoro, C, Kodali, M, Kabir, S, Soavi, F, Serov, A, Atanassov, P, Santoro C, Kodali M, Kabir S, Soavi F, Serov A, Atanassov P, Santoro, C, Kodali, M, Kabir, S, Soavi, F, Serov, A, Atanassov, P, Santoro C, Kodali M, Kabir S, Soavi F, Serov A, and Atanassov P

Abstract

Three-dimensional graphene nanosheets (3D-GNS) were used as cathode catalysts for microbial fuel cells (MFCs) operating in neutral operating conditions. 3D-GNS catalysts showed high performance towards oxygen electroreduction in neutral media with high current densities and low hydrogen peroxide generation compared to activated carbon (AC). 3D-GNS was incorporated into air-breathing cathodes based on AC with three different loadings (2, 6 and 10 mgcm-2). Performances in MFCs showed that 3D-GNS had the highest performances with power densities of 2.059±0.003 Wm-2, 1.855±0.007 Wm-2 and 1.503±0.005 Wm-2 for loading of 10, 6 and 2 mgcm-2 respectively. Plain AC had the lowest performances (1.017±0.009 Wm-2). The different cathodes electrodes were also investigated in supercapacitive MFCs (SC-MFCs). The addition of 3D-GNS decreased the ohmic losses by 14-25%. The decrease in ohmic losses allowed the SC-MFC with 3D-GNS (loading 10 mgcm-2) to have the maximum power (Pmax) of 5.746±0.186 Wm-2. At 5 mA, the SC-MFC featured a capacitive response that increased from 0.027±0.007 F with AC to 0.213±0.026 F with 3D-GNS (loading 2 mgcm-2) and further to 1.817±0.040 F with 3D-GNS (loading 10 mgcm-2). This is the first time that a capacitance of the order of magnitude of Farads is shown related to microbial fuel cell system.

Published
2017

21. Supercapacitive Microbial Desalination Cells: New Class of Power Generating Devices for Reduction of Salinity Content.

Author

Santoro, C, Benito Abad, F, Serov, A, Kodali, M, Howe, K, Soavi, F, Atanassov, P, Santoro C, Benito Abad F, Serov A, Kodali M, Howe KJ, Soavi F, Atanassov P, Santoro, C, Benito Abad, F, Serov, A, Kodali, M, Howe, K, Soavi, F, Atanassov, P, Santoro C, Benito Abad F, Serov A, Kodali M, Howe KJ, Soavi F, and Atanassov P

Abstract

In this work, the electrodes of a microbial desalination cell (MDC) are investigated as the positive and negative electrodes of an internal supercapacitor. The resulting system has been named a supercapacitive microbial de- salination cell (SC-MDC). The electrodes are self-polarized by the red-ox reactions and therefore the anode acts as a negative electrode and the cathode as a positive electrode of the internal supercapacitor. In order to overcome cathodic losses, an additional capacitive electrode (AdE) was added and short-circuited with the SC- MDC cathode (SC-MDC-AdE). A total of 7600 discharge/self-recharge cycles (equivalent to 44 h of operation) of SC-MDC-AdE with a desalination chamber filled with an aqueous solution of 30 g L−1 NaCl are reported. The same reactor system was operated with real seawater collected from Pacific Ocean for 88 h (15,100 cycles). Maximum power generated was 1.63 ± 0.04 W m−2 for SC-MDC and 3.01 ± 0.01 W m−2 for SC-MDC-AdE. Solution conductivity in the desalination reactor decreased by ∼50% after 23 h and by more than 60% after 44 h. There was no observable change in the pH during cell operation. Power/current pulses were generated without an external power supply.

Published
2017

22. Co-generation of hydrogen and power/current pulses from supercapacitive MFCs using novel HER iron-based catalysts

Author

Santoro C, Soavi F, Arbizzani C, Serov A, Kabir S, Bretschger O, Carpenter K, Atanassov P., Santoro, C, Soavi, F, Arbizzani, C, Serov, A, Kabir, S, Bretschger, O, Carpenter, K, and Atanassov, P

Subjects
hydrogen evolution, microbial fuel cell, Supercapacitor, microbial fuel cells, PGM-free, PGM-free catalysts, HER, bioenergy, Article, Power generation
Abstract

Highlights • Supercapacitive MFC boosted up power/current pulses. • In-series connection of 4 microbial fuel cells quadrupled voltage and power output. • Fe-catalysts showed high hydrogen evolution reaction rate in neutral media. • Co-generation of electricity and hydrogen using SC-MFCs is here demonstrated., In this work, four different supercapacitive microbial fuel cells (SC-MFCs) with carbon brush as the anode and an air-breathing cathode with Fe-Aminoantipyrine (Fe-AAPyr) as the catalyst have been investigated using galvanostatic discharges. The maximum power (Pmax) obtained was in the range from 1.7 mW to 1.9 mW for each SC-MFC. This in-series connection of four SC-MFCs almost quadrupled Pmax to an operating voltage of 3025 mV and a Pmax of 8.1 mW, one of the highest power outputs reported in the literature. An additional electrode (AdHER) connected to the anode of the first SC-MFC and placed in the fourth SC-MFC evolved hydrogen. The hydrogen evolution reaction (HER) taking place at the electrode was studied on Pt and two novel platinum group metal-free (PGM-free) catalysts: Fe-Aminoantipyrine (Fe-AAPyr) and Fe-Mebendazole (Fe-MBZ). The amount of H2 produced was estimated using the Faraday law as 0.86 mMd−1cm−2 (0.132 L day−1) for Pt, 0.83 mMd−1cm−2 (0.127 L day−1) for Fe-AAPyr and 0.8 mMd−1cm−2 (0.123 L day−1) for Fe-MBZ. Hydrogen evolution was also detected using gas chromatography. While HER was taking place, galvanostatic discharges were also performed showing simultaneous H2 production and pulsed power generation with no need of external power sources.

Published
2016

23. Supercapacitive Microbial Fuel Cell: Characterization and analysis for improved charge storage/delivery performance

Author

Houghton, J, Santoro, C, Soavi, F, Serov, A, Ieropoulos, I, Arbizzani, C, Atanassov, P, Houghton J, Santoro C, Soavi F, Serov A, Ieropoulos I, Arbizzani C, Atanassov P., Houghton, J, Santoro, C, Soavi, F, Serov, A, Ieropoulos, I, Arbizzani, C, Atanassov, P, Houghton J, Santoro C, Soavi F, Serov A, Ieropoulos I, Arbizzani C, and Atanassov P.

Abstract

Supercapacitive microbial fuel cells with various anode and cathode dimensions were investigated in order to determine the effect on cell capacitance and delivered power quality. The cathode size was shown to be the limiting component of the system in contrast to anode size. By doubling the cathode area, the peak power output was improved by roughly 120% for a 10 ms pulse discharge and internal resistance of the cell was decreased by $47%. A model was constructed in order to predict the perfor- mance of a hypothetical cylindrical MFC design with larger relative cathode size. It was found that a small device based on conventional materials with a volume of approximately 21 cm3 would be capable of delivering a peak power output of approximately 25 mW at 70 mA, corresponding to 1300 W m"3.

Published
2016

24. Miniaturized supercapacitors: key materials and structures towards autonomous and sustainable devices and systems

Author

Soavi, F, Bettini, L, Piseri, P, Milani, P, Santoro, C, Atanassov, P, Arbizzani, C, Soavi F, Bettini LG, Piseri P, Milani P, Santoro C, Atanassov P, Arbizzani C, Soavi, F, Bettini, L, Piseri, P, Milani, P, Santoro, C, Atanassov, P, Arbizzani, C, Soavi F, Bettini LG, Piseri P, Milani P, Santoro C, Atanassov P, and Arbizzani C

Abstract

Supercapacitors (SCs) are playing a key role for the development of self-powered and self-sustaining integrated systems for different fields ranging from remote sensing, robotics and medical devices. SC miniaturization and integration into more complex systems that include energy harvesters and func- tional devices are valuable strategies that address system autonomy. Here, we discuss about novel SC fabrication and integration approaches. Specifically, we report about the results of interdisciplinary ac- tivities on the development of thin, flexible SCs by an additive technology based on Supersonic Cluster Beam Deposition (SCBD) to be implemented into supercapacitive electrolyte gated transistors and supercapacitive microbial fuel cells. Such systems integrate at materials level the specific functions of devices, like electric switch or energy harvesting with the reversible energy storage capability. These studies might open new frontiers for the development and application of new multifunction-energy storage elements.

Published
2016

25. Co-generation of hydrogen and power/current pulses from supercapacitive MFCs using novel HER iron-based catalysts

Author

Santoro, C, Soavi, F, Arbizzani, C, Serov, A, Kabir, S, Bretschger, O, Carpenter, K, Atanassov, P, Santoro C, Soavi F, Arbizzani C, Serov A, Kabir S, Bretschger O, Carpenter K, Atanassov P., Santoro, C, Soavi, F, Arbizzani, C, Serov, A, Kabir, S, Bretschger, O, Carpenter, K, Atanassov, P, Santoro C, Soavi F, Arbizzani C, Serov A, Kabir S, Bretschger O, Carpenter K, and Atanassov P.

Abstract

In this work, four different supercapacitive microbial fuel cells (SC-MFCs) with carbon brush as the anode and an air-breathing cathode with Fe-Aminoantipyrine (Fe-AAPyr) as the catalyst have been investigated using galvanostatic discharges. The maximum power (Pmax) obtained was in the range from 1.7 mW to 1.9 mW for each SC-MFC. This in-series connection of four SC-MFCs almost quadrupled Pmax to an operating voltage of 3025 mV and a Pmax of 8.1 mW, one of the highest power outputs reported in the literature. An additional electrode (AdHER) connected to the anode of the first SC-MFC and placed in the fourth SC-MFC evolved hydrogen. The hydrogen evolution reaction (HER) taking place at the electrode was studied on Pt and two novel platinum group metal-free (PGM-free) catalysts: Fe-Aminoantipyrine (Fe-AAPyr) and Fe-Mebendazole (Fe-MBZ). The amount of H2 produced was estimated using the Faraday law as 0.86 mMd-1cm-2 (0.132 LH2 day-1) for Pt, 0.83 mMd-1cm-2 (0.127 LH2 day-1) for Fe-AAPyr and 0.8 mMd-1cm-2 (0.123 LH2 day-1) for Fe-MBZ. Hydrogen evolution was also detected using gas chromatography. While HER was taking place, galvanostatic discharges were also performed showing simultaneous H2 production and pulsed power generation with no need of external power sources.

Published
2016

26. Self-Powered Supercapacitive Microbial Fuel Cell: The Ultimate Way of Boosting and Harvesting Power

Author

Santoro, C, Soavi, F, Serov, A, Arbizzani, C, Atanassov, P, Santoro C, Soavi F, Serov A, Arbizzani C, Atanassov P, Santoro, C, Soavi, F, Serov, A, Arbizzani, C, Atanassov, P, Santoro C, Soavi F, Serov A, Arbizzani C, and Atanassov P

Abstract

In this work, for the first time, we demonstrate a supercapacitive microbial fuel cell which integrates the energy harvesting function of a microbial fuel cell (MFC) with the high-power operation of an internal supercapacitor. The pursued strategies are: (i) the increase of the cell voltage by the use of high potential cathodes like bilirubin oxidase (BOx) or iron-aminoantipyrine (Fe-AAPyr); (ii) the use of an additional capacitive electrode (additional electrode, AdE) which is short-circuited with the MFC cathode and coupled with the MFC anode (MFC-AdE). The high working potential of BOx cathode and the low impedances of the additional capacitive electrode and the MFC anode permitted to achieve up to 19mW (84.4Wm-2, 152Wm-3), the highest power value ever reported for MFCs. Exploiting the supercapacitive properties of the MFC electrodes allows the system to be simpler, cheaper and more efficient without additional electronics management added with respect to an MFC/external supercapacitor coupling. The use of the AdE makes it possible to decouple energy and power and to achieve recharge times in the order of few seconds making the system appealing for practical applications.

Published
2016

34. Air-breathing cathode self-powered supercapacitive microbial fuel cell with human urine as electrolyte

Author

Carlo Santoro, Francesca Soavi, Ioannis Ieropoulos, Xavier Alexis Walter, John Greenman, Santoro, C, Walter, X, Soavi, F, Greenman, J, Ieropoulos, I, Santoro C., Walter X.A., Soavi F., Greenman J., and Ieropoulos I.

Subjects
Microbial fuel cell, Materials science, Maximum power principle, General Chemical Engineering, Analytical chemistry, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, Capacitance, Article, Galvanostatic discharge, law.invention, law, Electrochemistry, Human urine, Current/power pulses, Equivalent series resistance, 021001 nanoscience & nanotechnology, Cathode, 0104 chemical sciences, Anode, Electrode, Galvanostatic discharges, Current/power pulse, Supercapacitive mode, 0210 nano-technology
Abstract

In this work, a membraneless microbial fuel cell (MFC) with an empty volume of 1.5 mL, fed continuously with hydrolysed urine, was tested in supercapacitive mode (SC-MFC). In order to enhance the power output, a double strategy was used: i) a double cathode was added leading to a decrease in the equivalent series resistance (ESR); ii) the apparent capacitance was boosted up by adding capacitive features on the anode electrode. Galvanostatic (GLV) discharges were performed at different discharge currents. The results showed that both strategies were successful obtaining a maximum power output of 1.59 ± 0.01 mW (1.06 ± 0.01 mW mL−1) at pulse time of 0.01 s and 0.57 ± 0.01 mW (0.38 ± 0.01 mW mL−1) at pulse time of 2 s. The highest energy delivered at ipulse equal to 2 mA was 3.3 ± 0.1 mJ. The best performing SC-MFCs were then connected in series and parallel and tested through GLV discharges. As the power output was similar, the connection in parallel allowed to roughly doubling the current produced. Durability tests over ≈5.6 days showed certain stability despite a light overall decrease., Graphical abstract Image 1, Highlights • Air-breathing microbial fuel cell was tested in supercapacitive mode. • A double cathode addition lead to a decrease in ohmic resistance. • Apparent capacitance was boosted up by adding capacitive features. • Maximum power output of 1.59 mW (1.06 mW mL−1) was reached at tpulse 0.01s. • Series and parallel connections improved the galvanostatic discharges.

Published
2020

35. Supercapacitive Operational Mode in Microbial Fuel Cell

Author

Francesca Soavi, Carlo Santoro, Soavi, F, Santoro, C, Soavi F., and Santoro C.

Subjects
Microbial fuel cells, Supercapacitive, Discharges, Self-recharges, High power/current generation, Microbial fuel cell, Materials science, Microbial fuel cells, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, Electrode, Self-recharge, Self-recharges, Electrochemistry, Discharge, Discharges, High power/current generation, 0210 nano-technology, Supercapacitive
Abstract

Supercapacitive microbial fuel cells (SC-MFCs) are an emerging and promising field that has captured the attention of scientists in the past few years. This hybridization consists in the integration of supercapacitive features in the MFC electrodes to boost the performance output. The MFC anaerobic and aerobic enviroments induce self-polarization of the electrodes. The electrodes can be discharged galvanostatically and then self-recharged by the biotic/abiotic environments. During the discharge, two main phenomena named electrostatic and faradaic take place but the separation and quantification of the two contributes seems to be challenging. Galvanostatic discharges of SC-MFC produce at least one order of magnitude higher current/power compared with continuous operations, making it promising for pulsed type applications.

Published
2020
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36. Valorization of the inedible pistachio shells into nanoscale transition metal and nitrogen codoped carbon-based electrocatalysts for hydrogen evolution reaction and oxygen reduction reaction

Author

Mohsin Muhyuddin, Nicolo’ Zocche, Roberto Lorenzi, Chiara Ferrara, Federico Poli, Francesca Soavi, Carlo Santoro, Muhyuddin, M, Zocche, N, Lorenzi, R, Ferrara, C, Poli, F, Soavi, F, and Santoro, C

Subjects
Fuel Technology, Circular economy, Renewable Energy, Sustainability and the Environment, Materials Chemistry, Electrocatalyst, Waste pistachio, Hydrogen evolution reaction, Oxygen reduction reaction, Electronic, Optical and Magnetic Materials
Abstract

Making a consistency with the objectives of circular economy, herein, waste pistachios shells were utilized for the development of hydrogen evolution reaction (HER) and oxygen reduction reaction (ORR) electrocatalysts which are the key bottleneck in the technological evolution of electrolyzers and fuel cells, respectively. As an alternative to scarce and expensive platinum-group-metal (PGM) electrocatalysts, metal nitrogen carbons (MNCs) are emerging as a promising candidate for both aforementioned electrocatalysis where iron and nickel are the metal of choice for ORR and HER, respectively. Therefore, FeNCs and NiNCs were fabricated utilizing inedible pistachio shells as a low-cost biosource of carbon. The steps involved in the fabrication of electrocatalyst were correlated with electrochemical performance in alkaline media. Encouraging onset potential of ~ 0.88 V vs RHE with a possibility of a 2 + 2 reaction pathway was observed in pyrolyzed and ball-milled FeNC. However, HF etching for template removal slightly affected the kinetics and eventually resulted in a relatively higher yield of peroxide. In parallel, the pyrolyzed NiNC demonstrated a lower HER overpotential of ~ 0.4 V vs RHE at − 10 mA cm−2. Nevertheless, acid washing adversely affected the HER performance and consequently, very high overpotential was witnessed.

Published
2022
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37. Giving New Life to Waste Cigarette Butts: Transformation into Platinum Group Metal-Free Electrocatalysts for Oxygen Reduction Reaction in Acid, Neutral and Alkaline Environment

Author

Davide Testa, Giovanni Zuccante, Mohsin Muhyuddin, Roberto Landone, Axel Scommegna, Roberto Lorenzi, Maurizio Acciarri, Elisabetta Petri, Francesca Soavi, Lorenzo Poggini, Laura Capozzoli, Alessandro Lavacchi, Niccolò Lamanna, Andrea Franzetti, Luca Zoia, Carlo Santoro, Testa, D, Zuccante, G, Muhyuddin, M, Landone, R, Scommegna, A, Lorenzi, R, Acciarri, M, Petri, E, Soavi, F, Poggini, L, Capozzoli, L, Lavacchi, A, Lamanna, N, Franzetti, A, Zoia, L, and Santoro, C

Subjects
oxygen reduction reaction, waste cigarettes, char, PGM-free, electrocatalysis, electrocatalysi, waste cigarette, Physical and Theoretical Chemistry, Catalysis, General Environmental Science
Abstract

Following the core theme of a circular economy, a novel strategy to upcycle cigarette butt waste into platinum group metal (PGM)-free metal nitrogen carbon (M-N-C) electrocatalysts for oxygen reduction reaction (ORR) is presented. The experimental route was composed of (i) the transformation of the powdered cigarette butts into carbonaceous char via pyrolysis at 450 °C, 600 °C, 750 °C and 900 °C, (ii) the porosity activation with KOH and (iii) the functionalization of the activated chars with iron (II) phthalocyanine (FePc). The electrochemical outcomes obtained by the rotating disk electrode (RRDE) technique revealed that the sample pyrolyzed at 450 °C (i.e., cig_450) outperformed the other counterparts with its highest onset (Eon) and half-wave potentials (E1/2) and demonstrated nearly tetra-electronic ORR in acidic, neutral and alkaline electrolytes, all resulting from the optimal surface chemistry and textural properties.

Published
2023
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38. Electrochemical stability of steel, Ti, and Cu current collectors in water-in-salt electrolyte for green batteries and supercapacitors

Author

Luca Sergi, Walter Giurlani, Francesca Soavi, Federico Poli, Nicola Calisi, Massimo Innocenti, Eugenio Crestini, Giurlani W., Sergi L., Crestini E., Calisi N., Poli F., Soavi F., and Innocenti M.

Subjects
Supercapacitor, Materials science, Battery, chemistry.chemical_element, Electrolyte, Chronoamperometry, Electrochemical stability, Condensed Matter Physics, Electrochemistry, Water-in-salt, Cathodic protection, chemistry, Chemical engineering, General Materials Science, Electrical and Electronic Engineering, Cyclic voltammetry, Current collector, Titanium, Electrochemical window
Abstract

The electrochemical behaviour of steel, copper, and titanium current collectors was studied in aqueous solutions of lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) at various concentrations, from 0.5 up to 20 m. As the concentration of the electrolyte increases, the electrochemical window of water stability widens according to the “water-in-salt” concept. The metal grids have been studied electrochemically, both under anodic and cathodic conditions, by means of cyclic voltammetry and chronoamperometry. Subsequently, a microscopic analysis with SEM and compositional analysis with XPS was carried out to evaluate the surface modifications following electrochemical stress. We found that copper is not very suitable for this kind of application, while titanium and steel showed interesting behaviour and large electrochemical window.

Published
2020
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39. Electrodeposition of Cobalt-Copper Oxides Decorated with Conductive Polymer for Supercapacitor Electrodes with High Stability

Author

E. Noormohammadi, F. Poli, C. Durante, M. Lunardon, S. Sanjabi, F. Soavi, Noormohammadi, E, Poli, F, Durante, C, Lunardon, M, Sanjabi, S, and Soavi, F

Subjects
Electrodeposition, PSS, Cobalt-copper oxides, Conductive polymer, Cycling stability, PEDOT, Supercapacitor electrode, Electrochemistry, Cobalt-copper oxide, Catalysis
Abstract

Here, we report about the synthesis of Cobalt-Copper (CC) mixed oxides prepared by electrodeposition and thermal annealing, and coated with PEDOT:PSS (CCP) for supercapacitor electrodes. The electrodes' morphology and electrochemical performance were investigated by combining XRD, XPS, SEM, cyclic voltammetry, and galvanostatic charge/discharge tests. The initial capacity of the CC electrode was 26 mAh/g at a scan rate of 5 mV/s with a coulombic efficiency of 92 %. The CC electrode featured a capacity retention of 81 % at a constant current density of 1 A/g after 5000 cycles. CCP electrodes slightly reduced the specific capacity but increased both coulombic efficiency and cyclic stability. CCP1 electrode featured a specific capacity of 21 mAh/g at 5 mV/s scan rate with better coulombic efficiency 95 % along with capacity retention of 92.3 % over 5000 cycles. Increasing the amount of PEDOT:PSS lowered the CC electrodes' specific capacity, but significantly improved the capacity retention up to 100 %.

Published
2022

40. Biosourced quinones for high-performance environmentally benign electrochemical capacitors via interface engineering

Author

Abdelaziz Gouda, Alexandre Masson, Molood Hoseinizadeh, Francesca Soavi, Clara Santato, Gouda, A, Masson, A, Hoseinizadeh, M, Soavi, F, and Santato, C

Subjects
Materials Chemistry, Environmental Chemistry, Quinone, General Chemistry, supercapacitor, interface engineering, Biochemistry
Abstract

Biosourced and biodegradable organic electrode materials respond to the need for sustainable storage of renewable energy. Here, we report on electrochemical capacitors based on electrodes made up of quinones, such as Sepia melanin and catechin/tannic acid (Ctn/TA), solution-deposited on carbon paper engineered to create high-performance interfaces. Sepia melanin and Ctn/TA on TCP electrodes exhibit a capacitance as high as 1355 mF cm(-2) (452 F g(-1)) and 898 mF cm(-2) (300 F g(-1)), respectively. Sepia melanin and Ctn/TA symmetric electrochemical capacitors operating in aqueous electrolytes exhibit up to 100% capacitance retention and 100% coulombic efficiency over 50,000 and 10,000 cycles at 150 mA cm(-2) (10 A g(-1)), respectively. Maximum power densities as high as 1274 mW cm(-2) (46 kW kg(-1)) and 727 mW cm(-2) (26 kW kg(-1)) with maximum energy densities of 0.56 mWh cm(-2) (20 Wh kg(-1)) and 0.65 mWh cm(-2) (23 Wh kg(-1)) are obtained for Sepia melanin and Ctn/TA.Biosourced and biodegradable organic electrode materials are investigated for environmentally benign energy storage, but their performance at higher current density is often poor. Here, the authors construct electrodes with quinone-based species from Sepia melanin and tannins on treated carbon paper and observe electrode capacitance as high as 1355 mF cm(-2) at current densities up to 10 A g(-1).

Published
2022

42. Correlating Structure and Properties of Super‐Concentrated Electrolyte Solutions: 17 O NMR and Electrochemical Characterization

Author

Francesca De Giorgio, Irene Ruggeri, Andrea La Monaca, Vittorio Berbenni, Chiara Ferrara, Catia Arbizzani, Piercarlo Mustarelli, Francesca Soavi, Ruggeri, I, La Monaca, A, De Giorgio, F, Soavi, F, Arbizzani, C, Berbenni, V, Ferrara, C, Mustarelli, P, and Irene Ruggeri, Andrea La Monaca, Francesca De Giorgio, Francesca Soavi, Catia Arbizzani, Vittorio Berbenni, Chiara Ferrara, Piercarlo Mustarelli

Subjects
Materials science, solvent in salt solution, Li NMR, solvent in salt solutions (SIS), Electrolyte, Electrochemistry, 7Li NMR, O NMR, Catalysis, glyme, Characterization (materials science), Chemical engineering, 17O NMR, solvent in salt solutions, ⁷Li NMR, ¹⁷O NMR
Abstract

This is the peer reviewed version of the following article: Correlating Structure and Properties of Super-concentrated Electrolyte Solutions: 17O NMR and Electrochemical Characterization, Irene Ruggeri, Andrea La Monaca, Francesca De Giorgio, Francesca Soavi, Catia Arbizzani, Vittorio Berbenni, Chiara Ferrara, Piercarlo Mustarelli, ChemElectroChem 2019, 6, 4002–4009, which has been published in final form at https://doi.org/10.1002/celc.201900829. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions. This article may not be enhanced, enriched or otherwise transformed into a derivative work, without express permission from Wiley or by statutory rights under applicable legislation. Copyright notices must not be removed, obscured or modified. The article must be linked to Wiley’s version of record on Wiley Online Library and any embedding, framing or otherwise making available the article or pages thereof by third parties from platforms, services and websites other than Wiley Online Library must be prohibited. &nbsp

Published
2019
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43. Increasing bioelectricity generation in microbial fuel cells by a high-performance cellulose-based membrane electrode assembly

Author

Mahdi Mashkour, Mehrdad Mashkour, Francesca Soavi, Mostafa Rahimnejad, Mashkour M., Rahimnejad M., and Soavi F.

Subjects
Materials science, Microbial fuel cell, 020209 energy, Capacitance, Single chamber microbial fuel cell, 02 engineering and technology, Energy supply, Management, Monitoring, Policy and Law, Internal resistance, Electrochemistry, Bacterial cellulose, chemistry.chemical_compound, 020401 chemical engineering, Nafion, 0202 electrical engineering, electronic engineering, information engineering, Membrane electrode assembly, 0204 chemical engineering, Nano-zycosil, Gas diffusion electrode, Mechanical Engineering, Building and Construction, Anode, General Energy, chemistry, Chemical engineering
Abstract

Economically harvesting energy from a microbial fuel cell (MFC), increasing its electrical power production, and developing its role as a practical energy supply, needs a low-cost and high-performance design of the MFC compartments. According to this strategy, a novel monolithic membrane electrode assembly (MEA) was fabricated and evaluated as an air–cathode in a single-chamber MFC (SCMFC). The MEA was made of bacterial cellulose (BC), conductive multi-walled carbon nanotubes (CNT), and nano-zycosil (NZ). BC, as a nano-celluloses with oxygen barrier property, can maintain anaerobic conditions for the anode compartment. Binder-less CNT coating on BC avoids costly binders such as poly-tetra fluoro ethylene (PTFE) and Nafion and decreases the MEA charge transfer resistance. NZ, as a very cheap modifier, not only prevents the anolyte leakage but also provides more MEA’s active sites for the oxygen reduction reaction (ORR). The electrochemical performance of the MEA was compared to a PTFE- based gas diffusion electrode (GDE) in the SCMFC. The MEA cell provided a pulse power density of 1790 mW/m2, roughly twice as high as the pulse power density of GDE (920 mW/m2). SCMFC’s internal resistance decreased from 1.84 KΩ (with GDE) to 0.8 KΩ (with MEA). Also, the cell’s columbic efficiency increased from 4.2% (with GDE) to11.7% (with MEA). Additionally, the capacitance of the MEA (65 mF) was much higher than the value for GDE (0.73 mF). Thus, the MEA compared to the GDE showed higher performance in the SCMFC for electricity generation and wastewater treatment at a lower cost.

Published
2021

44. Redox flow batteries: Status and perspective towards sustainable stationary energy storage

Author

Edgar Ventosa, Estibaliz Aranzabe, Raquel Ferret, Rebeca Marcilla, Eduardo Sánchez-Díez, Francesca Soavi, Petr Mazúr, Massimo Guarnieri, Andrea Trovò, Cristina Flox, Consorcio de innovación y desarrollo, Universidad de Burgos, University of Padova, Department of Chemistry and Materials Science, IMDEA Institute, Universita di Bologna, University of West Bohemia, IK4 Research Alliance, Aalto-yliopisto, Aalto University, Sanchez-Diez E., Ventosa E., Guarnieri M., Trovo A., Flox C., Marcilla R., Soavi F., Mazur P., Aranzabe E., and Ferret R.

Subjects
Electrochemical energy storage, Redox-flow batteries, Stationary energy storage, Sustainable energy, Computer science, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Energy storage, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Renewable Energy, Sustainability and the Environment, business.industry, Química analítica, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Renewable energy, Risk analysis (engineering), Redox-flow batterie, Chemistry, Analytic, 0210 nano-technology, business
Abstract

Redox-flow batteries, based on their particular ability to decouple power and energy, stand as prime candidates for cost-effective stationary storage, particularly in the case of long discharges and long storage times. Integration of renewables and subsequent need for energy storage is promoting effort on the development of mature and emerging redox-flow technologies. This review aims at providing a critical analysis of redox-flow technologies that can potentially fulfill cost requirements and enable large scale storage, mainly aqueous based systems. A comprehensive overview of the status of those technologies, including advantages and weaknesses, is presented. Compiled data on the market permeability, performance and cost should serve, together with the perspective included, to understand the different strategies to reach the successful implementation, from component development to innovative designs., European Union under HIGREEW, Affordable High-performance Green Redox Flow batteries (Grant Agreement no. 875613) and CuBER, Copper-Based Flow Batteries for energy storage renewables integration (Grant agreement no: 875605) projects. Basque Government (GV-ELKARTEK-2020 KK-2020/00078), Spanish MINECO (RTI2018-099228-A-I00 and RYC2018-026086-I (Ramon y Cajal fellowship) E.V.) and CDTI (Centro para el Desarrollo Tecnológico Industrial, CER-20191006) are also acknowledged for funding this work. R.M. thanks the European Research Council (ERC) through “MFreeB” project (grant agreement no. 726217)

Published
2020

45. Enhanced electrodialytic bioleaching of fly ashes of municipal solid waste incineration for metal recovery

Author

Enrico Dinelli, Francesca Soavi, Helena I. Gomes, Valerio Funari, Gomes H.I., Funari V., Dinelli E., and Soavi F.

Subjects
Circular economy, General Chemical Engineering, Ph control, Mixing (process engineering), Resource recovery, Waste management, Biotechnology, Combined technologies, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Metal, Bioleaching, Electrochemistry, Combined method, Chemistry, Electrodialysis, 021001 nanoscience & nanotechnology, Pulp and paper industry, 0104 chemical sciences, Acidophilic bacteria, Combined technologie, visual_art, Municipal solid waste incineration, visual_art.visual_art_medium, 0210 nano-technology
Abstract

© 2020 Elsevier Ltd Metal recovery from wastes is essential for a circular economy and minimising present-day society environmental footprint. In this study, we combined electrodialysis with bioleaching of fly ashes for enhanced metal recovery from municipal solid waste incineration residues. Results showed that the use of low-level direct current with acidophilic bacteria enhanced metal recovery in the catholyte when compared to the abiotic experiment supplied with direct current and the bioleaching experiment without direct current. The use of electrodialysis with bioleaching showed increased performance on the removal and recovery of metals in the catholyte such as Al, Cd, Co, Li, Pb, and Zn. While Co and Ni were selectively mobilised by bioleaching, Cu, Cr, Cd and Li showed highly elevated concentrations by combining both techniques. These results are proof of concept of combined methods will allow optimising the process, especially varying the liquid to solid ratio, mixing, duration of the experiments, and pH control in the anolyte.

Published
2020
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46. Comparison and Modeling of Commercial Supercapacitors via Standardized Potentiostatic Electrochemical Impedance Spectroscopy

Author

Maria Luisa Di Vona, Giuseppe Taddia, Francesca Soavi, Sandro Tenconi, Alessandro Lampasi, Miguel Pretelli, Filippo Gherdovich, Gherdovich, F., Taddia, G., Tenconi, S. M., Pretelli, M., Lampasi, A., Soavi, F., Di Vona, M. L., W. Zamboni, G. Petrone, and Filippo Gherdovich, Giuseppe Taddia, Sandro Maria Tenconi, Miguel Pretelli, Alessandro Lampasi, Francesca Soavi, and Maria Luisa DiVona

Subjects
Supercapacitor, Materials science, Energy storage systems, Capacitive sensing, Capacitance, Electronic circuit simulation, Potentiostat, Dielectric spectroscopy, visual_art, Electronic component, Modelling, Supercapacior, Electrochemical Impedance Spectroscopy, visual_art.visual_art_medium, Electronic engineering, Nyquist plot, Electrochemical impedance spectroscopy
Abstract

The main scope of the study is the characterization of the capacitive and resistive behavior of two supercapacitor cells and one hybrid supercapacitor available on the market, through potentiostatic electrochemical impedance spectroscopy (PEIS). The PEIS tests were performed by applying to all cells the same voltage perturbation in the same frequency range. In a first phase, the instrumentation used for the acquisitions was optimized, with particular care to the connections between the potentiostat and the supercapacitor cell. The Nyquist diagrams obtained for each sample are compared and capacitance/frequency graphs are deduced. The technological differences between various devices are then discussed in relation to the results. The characterization of the sample cells and the collected data are used to propose the corresponding models conceived for circuit simulation. These models are based on simple electronic components available in the standard circuit simulation software tools.

Published
2020
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47. Electro-polymerized polyaniline modified conductive bacterial cellulose anode for supercapacitive microbial fuel cells and studying the role of anodic biofilm in the capacitive behavior

Author

Mostafa Rahimnejad, Mehrdad Mashkour, Francesca Soavi, Mahdi Mashkour, Mashkour M., Rahimnejad M., and Soavi F.

Subjects
Materials science, Microbial fuel cell, Polyaniline, Energy Engineering and Power Technology, Capacitance, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Bacterial cellulose, chemistry.chemical_compound, Anodic biofilm, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Polarization (electrochemistry), Power density, Renewable Energy, Sustainability and the Environment, Impedance, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Anode, Membrane, chemistry, Chemical engineering, Electrode, Supercapacitive microbial fuel cell, 0210 nano-technology
Abstract

Polyaniline modified conductive bacterial cellulose (BC-CNT-PANI) membrane is proposed as a novel bioanode for microbial fuel cell (MFC). BC is coated with CNT by vacuum filtering to form a conductive electrode (BC-CNT). Then the conductive side is coated with PANI through a fast and easy electro-polymerization (BC-CNT-PANI). Both anode electrodes are studied in supercapacitive MFCs (SCMFCs) by impedance analysis before and after biofilm formation on their surface. By bacteria colonization on the anodes’ surface, charge transfer resistance (Rct) of BC-CNT increases significantly from 14.5 Ω to 72 Ω while for BC-CNT-PANI, Rct decreases by 50%. Also, after biofilm formation, BC-CNT-PANI achieves a capacitance two times higher than that of BC-CNT. The SCMFCs are assembled and tested with BC-CNT, BC-CNT-PANI, and the double-anode BC-CNT& BC-CNT-PANI. Polarization, power density and galvanostatic discharge tests imply on an improvement in the SCMFC performance by using BC-CNT-PANI. The performance of the SCMFCs are limited by the anodes. The power density improves by 20% with the PANI-modified anode compared to the BC-CNT.

Published
2020

48. Combination of bioelectrochemical systems and electrochemical capacitors: Principles, analysis and opportunities

Author

Leire Caizán-Juanarena, Carlo Santoro, Doekle Reinder Yntema, Ioannis Ieropoulos, Annemiek ter Heijne, Casper Borsje, Tom H. J. A. Sleutels, Francesca Soavi, Caizán-Juanarena, L, Borsje, C, Sleutels, T, Yntema, D, Santoro, C, Ieropoulos, I, Soavi, F, ter Heijne, A, Caizán-Juanarena, Leire, Borsje, Casper, Sleutels, Tom, Yntema, Doekle, Santoro, Carlo, Ieropoulos, Ioanni, Soavi, Francesca, and ter Heijne, Annemiek

Subjects
0106 biological sciences, Microbial fuel cell, Materials science, Bioelectric Energy Sources, Capacitive sensing, Capacitance, Bioengineering, Wastewater, 01 natural sciences, 7. Clean energy, Applied Microbiology and Biotechnology, Article, law.invention, 03 medical and health sciences, Electricity, law, Hardware_GENERAL, 010608 biotechnology, Process engineering, Electrodes, Power management system, 030304 developmental biology, Supercapacitor, 0303 health sciences, WIMEK, Scaling up, business.industry, Power output, Electrical double-layer, Bristol Bio-Energy Centre, 6. Clean water, Capacitor, Electricity generation, Microbial fuel cell, Capacitance, Electrical double-layer, Scaling up, Supercapacitor, Power output, Environmental Technology, Milieutechnologie, business, Energy harvesting, Biological Recovery & Re-use Technology, Biotechnology
Abstract

© 2019 The Authors Bioelectrochemical systems combine electrodes and reactions driven by microorganisms for many different applications. The conversion of organic material in wastewater into electricity occurs in microbial fuel cells (MFCs). The power densities produced by MFCs are still too low for application. One way of increasing their performance is to combine them with electrochemical capacitors, widely used for charge storage purposes. Capacitive MFCs, i.e. the combination of capacitors and MFCs, allow for energy harvesting and storage and have shown to result in improved power densities, which facilitates the up scaling and application of the technology. This manuscript summarizes the state-of-the-art of combining capacitors with MFCs, starting with the theory and working principle of electrochemical capacitors. We address how different electrochemical measurements can be used to determine (bio)electrochemical capacitance and show how the measurement data can be interpreted. In addition, we present examples of the combination of electrochemical capacitors, both internal and external, that have been used to enhance MFC performance. Finally, we discuss the most promising applications and the main existing challenges for capacitive MFCs.

Published
2020
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49. Pullulan-ionic liquid-based supercapacitor: A novel, smart combination of components for an easy-to-dispose device

Author

Francesca Soavi, Bridget K. Mutuma, Federico Poli, Antonio Terella, Ncholu I. Manyala, Damilola Y. Momodu, Maria Letizia Focarete, Giovanni Emanuele Spina, Poli F., Momodu D., Spina G.E., Terella A., Mutuma B.K., Focarete M.L., Manyala N., and Soavi F.

Subjects
Materials science, General Chemical Engineering, Nanotechnology, 02 engineering and technology, Electrolyte, Ionic liquid, 010402 general chemistry, 01 natural sciences, Pullulan, law.invention, chemistry.chemical_compound, law, Electrochemistry, Specific energy, Separator (electricity), Supercapacitor, Electrospinning, Bio-char carbon, 021001 nanoscience & nanotechnology, Green supercapacitor, 0104 chemical sciences, Capacitor, chemistry, 0210 nano-technology
Abstract

Strategies that simultaneously target energy/power performance, sustainable manufacturing processes, valorization of green raw materials, and easy recycling of supercapacitors are urgently needed. Today, efforts have to be devoted not only to improve system performance but also to address the sustainability of materials and devices manufacturing and recyclability. Specifically, pullulan is herein proposed as a novel bio-degradable binder and separator for green supercapacitors. It is processed by electrospinning from aqueous solutions, therefore overcoming issues related to conventional membrane processing by organic solvents. Furthermore, combining the water-soluble, biodegradable pullulan with a hydrophobic ionic liquid electrolyte brings about a novel approach for end-of-life management of devices. The use of pullulan is demonstrated in a supercapacitor with carbon electrodes obtained from pepper-seeds waste and 1-Ethyl-3-methylimidazoliumbis(trifluoromethylsulfonyl)imide as the electrolyte. The supercapacitor delivers up to 5 kW kg−1 specific power and 27.8 Wh kg−1 specific energy at 3.2 V, that well compare with conventional electrical double-layer capacitor performance with the added value of being eco-friendly and cheap.

Published
2020

50. Electronic Transport in the Biopigment Sepia Melanin

Author

Abdelaziz Gouda, Jonathan Bellemare, Francesca Soavi, Clara Santato, David Ménard, Jean-Michel Nunzi, Manuel Reali, Reali M., Gouda A., Bellemare J., Menard D., Nunzi J.-M., Soavi F., and Santato C.

Subjects
Antioxidant, bio-sourced material, medicine.medical_treatment, Biomedical Engineering, 02 engineering and technology, reversible resistive switching, 010402 general chemistry, 01 natural sciences, Biomaterials, Melanin, Pigment, Ink sac, electronic transport, bio-sourced materials, sustainable (green) organic electronics, medicine, Sepia, Sepia melanin, Chemistry, Biochemistry (medical), General Chemistry, 021001 nanoscience & nanotechnology, Melanoma skin cancer, 0104 chemical sciences, Metal chelation, Biochemistry, visual_art, Photoprotection, visual_art.visual_art_medium, sense organs, 0210 nano-technology, human activities
Abstract

Eumelanin is the most common form of the pigment melanin in the human body, with diverse functions including photoprotection, antioxidant behavior, metal chelation, and free radical scavenging. Melanin also plays a role in melanoma skin cancer and Parkinson’s disease. Sepia melanin is a natural eumelanin extracted from the ink sac of cuttlefish. Eumelanin is an ideal candidate to eco-design technologies based on abundant, biosourced, and biodegradable organic electronic materials to alleviate the environmental footprint of the electronics sector. Herein, the focus is on the reversible electrical resistive switching in dry and wet Sepia eumelanin pellets, pointing to the possibility of predominant electronic transport satisfying conditio sine qua non to develop melanin-based electronic devices. These findings shed light on the possibility to describe the transport physics of dry eumelanin using the amorphous semiconductor model. Results are of tremendous importance for the development of sustainable organic electronics.

Published
2020

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