High Performance Platinum Group Metal-Free Cathode Catalysts for Microbial Fuel Cell (MFC)

Kodali, Mounika; Gokhale, Rohan; Santoro, Carlo; Serov, Alexey; Artyushkova, Kateryna; Atanassov, Plamen

doi:10.1149/2.0061703jes

Cited by 53 publications

(38 citation statements)

References 53 publications

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“…Maximum power density achieved by the Fe-NCB cathode initially was 1.85 W m −2 (day 1) and then decrease by roughly 30% at 1.25 W m −2 after 22 days operations. The maximum power density here reported is comparable to the performance achieved by iron-based catalysts synthesized using the polymerization-pyrolysis method and a catalyst loading of 1 mgcm −2 [ [97] , [98] , [99] ]. The performance are instead slightly lower compared to other reported literature in which the peak of current density was above 2 Wm -2 when Fe-based catalyst was incorporated into the air-breathing cathode structure [ 17 , 18 , 43 , 44 , 47 , 50 , 56 , [67] , [68] , [69] ].…”

Section: Resultssupporting

confidence: 57%

Iron-Nicarbazin derived platinum group metal-free electrocatalyst in scalable-size air-breathing cathodes for microbial fuel cells

Erable¹,

Oliot²,

Lacroix³

et al. 2018

Electrochimica Acta

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In this work, a platinum group metal-free (PGM-free) catalyst based on iron as transitional metal and Nicarbazin (NCB) as low cost organic precursor was synthesized using Sacrificial Support Method (SSM). The catalyst was then incorporated into a large area air-breathing cathode fabricated by pressing with a large diameter pellet die. The electrochemical tests in abiotic conditions revealed that after a couple of weeks of successful operation, the electrode experienced drop in performances in reason of electrolyte leakage, which was not an issue with the smaller electrodes. A decrease in the hydrophobic properties over time and a consequent cathode flooding was suspected to be the cause. On the other side, in the present work, for the first time, it was demonstrated the proof of principle and provided initial guidance for manufacturing MFC electrodes with large geometric areas. The tests in MFCs showed a maximum power density of 1.85 W m−2. The MFCs performances due to the addition of Fe-NCB were much higher compared to the iron-free material. A numerical model using Nernst-Monod and Butler-Volmer equations were used to predict the effect of electrolyte solution conductivity and distance anode-cathode on the overall MFC power output. Considering the existing conditions, the higher overall power predicted was 3.6 mW at 22.2 S m−1 and at inter-electrode distance of 1 cm.

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Section: Resultssupporting

confidence: 57%

Iron-Nicarbazin derived platinum group metal-free electrocatalyst in scalable-size air-breathing cathodes for microbial fuel cells

Erable¹,

Oliot²,

Lacroix³

et al. 2018

Electrochimica Acta

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“…[26] Platinum is a very active catalyst, but it is extremely expensive and sensible to poisoning in the presence of anions. [27][28][29][30] Carbonaceous-based materials [31][32][33] and transition metal-containing catalysts [34][35][36][37] have replaced platinum successfully. The addition of transition metals and especially FeÀ NÀ C active sites has improved significantly the performance almost doubling the MFCs output.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2020

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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.

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“…Oxygen reduction reaction (ORR) suffers from numerous severe limitations when it occurs in neutral media, and therefore an optimization of the catalyst is needed to accelerate the process [8] , [9] , [10] . First, high activation overpotentials exist, being as high as 50–100 mV when enzymes are utilized [11] , [12] , [13] , [14] , 200–300 mV in the case of platinum based group metal (PGM) catalysts [15] , [16] or platinum group metal-free (PGM-free) catalysts [17] , [18] , [19] , [20] , [21] , [22] , and even larger in the case of bacterial catalyst [23] , [24] , [25] or carbonaceous materials [26] , [27] , [28] , [29] , [30] , [31] , [32] , [33] . Second, the ORR reaction kinetics is very slow mainly due to the neutral pH, in which both H + and OH − are present in low concentration and both of them participate directly as reactants of ORR, the first one via the acidic pathway and the second one via the alkaline pathway [5] , [6] , [25] .…”

Section: Introductionmentioning

confidence: 99%

Influence of platinum group metal-free catalyst synthesis on microbial fuel cell performance

Santoro

Rojas‐Carbonell

Awais

et al. 2018

Journal of Power Sources

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Platinum group metal-free (PGM-free) ORR catalysts from the Fe-N-C family were synthesized using sacrificial support method (SSM) technique. Six experimental steps were used during the synthesis: 1) mixing the precursor, the metal salt, and the silica template; 2) first pyrolysis in hydrogen rich atmosphere; 3) ball milling; 4) etching the silica template using harsh acids environment; 5) the second pyrolysis in ammonia rich atmosphere; 6) final ball milling. Three independent batches were fabricated following the same procedure. The effect of each synthetic parameters on the surface chemistry and the electrocatalytic performance in neutral media was studied. Rotating ring disk electrode (RRDE) experiment showed an increase in half wave potential and limiting current after the pyrolysis steps. The additional improvement was observed after etching and performing the second pyrolysis. A similar trend was seen in microbial fuel cells (MFCs), in which the power output increased from 167 ± 2 μW cm−2 to 214 ± 5 μW cm−2. X-ray Photoelectron Spectroscopy (XPS) was used to evaluate surface chemistry of catalysts obtained after each synthetic step. The changes in chemical composition were directly correlated with the improvements in performance. We report outstanding reproducibility in both composition and performance among the three different batches.

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High Performance Platinum Group Metal-Free Cathode Catalysts for Microbial Fuel Cell (MFC)

Cited by 53 publications

References 53 publications

Iron-Nicarbazin derived platinum group metal-free electrocatalyst in scalable-size air-breathing cathodes for microbial fuel cells

Iron-Nicarbazin derived platinum group metal-free electrocatalyst in scalable-size air-breathing cathodes for microbial fuel cells

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

Influence of platinum group metal-free catalyst synthesis on microbial fuel cell performance

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