Use of Pineapple Waste as Fuel in Microbial Fuel Cell for the Generation of Bioelectricity

Rojas-Flores, Segundo; Nazario-Naveda, Renny; Benites, Santiago M.; Gallozzo-Cardenas, Moisés; Delfín-Narciso, Daniel; Díaz, Félix

doi:10.3390/molecules27217389

Cited by 16 publications

(4 citation statements)

References 64 publications

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“…The optimal operating valu of each MFC vary, and different types of substrates used with different pH have be found in the literature; one of the main reasons for this phenomenon is that the microo ganisms are different and each one grows at specific pH conditions, affecting the syste performance [41,42] To calculate the internal resistance of the MFC-SC, Ohm's Law (V = IR) was used, where the voltage values were placed on the "y" axis and those of the electric current on the "x" axis, which when performing a linear adjustment, the slope of the line is the internal resistance of the system, see Figure 4a. Based on the work carried out by Christwardana et al (2020), this method represents an effective tool for the in-depth study of MFCs [16,44], as unlike the electrochemical impedance method (EIS) used in other investigations, internal resistance is obtained more directly. The IES method allows us to find the different components of the internal resistance, such as the resistance of charge transfer, diffusion, and resistance of the substrate, which is obtained with the intersection of the Nyquist curve with the "x" axis measured from the origin.…”

Section: Results and Analysismentioning

confidence: 99%

“…One of the highest values found in the literature was the one reported by Simeon et al (2020), where they were able to generate 725 mV peaks using urine treatment waste as a substrate in their MFC-SC with carbon electrodes, showing an initial and final internal resistance of 269.94 and 1627.89 Ω (by polarization method), respectively, resistance values increase from your control sample to the highest concentration of substrate (368.56 to 676.43 Ω) [43]. Figure 4b shows the power density (PD) values as a function of current density (CD), achieving a maximum power density of 264.72 ± 3.54 mW/cm 2 at a current density of 4.388 A/cm 2 with a peak voltage of 879.56 ± 0.184 V. The high values shown are due to the high inherent conductivity of the electrodes used, since being metallic in nature they facilitate the passage of electrons within the electrical circuit [44]. Other researchers have managed to generate higher values, but with the help of catalysts or biocatalysts, for example, Yaqoob et al ( 2022) managed to generate a maximum power density of 41.58 mW/m 2 with an internal resistance of 813.73 Ω using food waste (rice mixed with curry, vegetables, fish, cabbage, bones, and sweet cake pieces) as a substrate in MFC with graphite rod electrodes, compared to his control sample of 14.1 mW/m 2 , the increase was notorious [45].…”

Section: Results and Analysismentioning

confidence: 99%

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Green Energy Generated in Single-Chamber Microbial Fuel Cells Using Tomato Waste

et al. 2023

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This research used tomato waste as a substrate (fuel) in Single Chamber-Microbial Fuel Cells (scMFC) on a small scale. The electrochemical properties were monitored, the functional groups of the substrate were analyzed by Fourier Transform Infrared Spectrophotometry (FTIR) and a microbiological analysis was performed on the electrodes in order to identify the microorganisms responsible for the electrochemical process. The results show voltage peaks and an electrical current of 3.647 ± 0.157 mA and 0.957 ± 0.246 V. A pH of 5.32 ± 0.26 was measured in the substrate with an electrical current conductivity of 148,701 ± 5849 mS/cm and an internal resistance (Rint) of 77. 517 ± 8.541 Ω. The maximum power density (PD) displayed was 264.72 ± 3.54 mW/cm2 at a current density (CD) of 4.388 A/cm2. On the other hand, the FTIR spectrum showed a more intense decrease in its peaks, with the compound belonging to the phenolic groups being the most affected at 3361 cm−1. The micrographs show the formation of a porous biofilm where molecular identification allowed the identification of two bacteria (Proteus vulgaris and Proteus vulgaris) and a yeast (Yarrowia lipolytica) with 100% identity. The data found show the potential of this waste as a source of fuel for the generation of an electric current in a sustainable and environmentally friendly way, generating in the near future a mechanism for the reuse of waste in a beneficial way for farmers, communities and agro-industrial companies.

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Section: Results and Analysismentioning

confidence: 99%

Section: Results and Analysismentioning

confidence: 99%

Green Energy Generated in Single-Chamber Microbial Fuel Cells Using Tomato Waste

et al. 2023

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“…Likewise, Figure 3b shows the values of electrical conductivity, where the values increase from the first day (70.46 ± 1.73 mS/cm) to day 18 (140.07 ± 3.51 mS/cm) and then decrease slowly until the last day (45.98 ± 4.51 mS/cm). The increase in electrical conductivity values is due to the low electrical resistance of the substrate used, while these values begin to decline due to the sedimentation of organic compounds present in the waste used [42,43]. Substrate masses have also been reported to have a dependence on electrical conductivity According to Kalagbor et al (2020), this relationship is directly proportional because in their research, the masses increased from 1 to 12 Kg and their electrical conductivity values increased from 787.6 ± 475.89 to 1282.9 ± 492.94 mS/cm.…”

Section: Results and Analysismentioning

confidence: 99%

Use of Tangerine Waste as Fuel for the Generation of Electric Current

et al. 2023

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Fruit waste has increased exponentially worldwide, within which tangerine is one of those that generates a greater amount of organic waste, which is currently not fully used. On the other hand, microbial fuel cells (MFCs) are presented as an opportunity to take advantage of organic waste to generate electricity, which is why the main objective of this research is to generate bioelectricity using tangerine waste as a substrate in microbial fuel cells using zinc and copper electrodes. It was possible to generate current and voltage peaks of 1.43973 ± 0.05568 mA and 1.191 ± 0.035 V on days eighteen and seventeen, respectively, operating with an optimum pH of 4.78 ± 0.46 and with electrical conductivity of the substrate of 140.07 ± 3.51 mS/cm, while the Brix degrees gradually decreased until the last day. The internal resistance determined was 65.378 ± 1.967 Ω, while the maximum power density was 475.32 ± 24.56 mW/cm2 at a current density of 5.539 A/cm2 with a peak voltage of 1024.12 ± 25.16 mV. The bacterium (Serratia fonticola) and yeasts (Rhodotorula mucilaginosa) were identified in the substrate with an identity of 99.57 and 99.50%, respectively. Finally, the cells were connected in series, managing to generate 3.15 V, which allowed the turning on of a red LED light.

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“…It has been reported that in 100 g of this fruit, there is water (87 g), protein (1.1 g), fat (0.4 g), fiber (3 g), carbohydrates (11 g), iron (1.9 mg), vitamin B1 (0.04 mg), vitamin B2 (0.05 mg), vitamin B3 (0.16 mg), vitamin C (20.5 mg), calcium (8.5 mg), and phosphorus (22.5 mg), which have appropriate properties for medical and diuretic uses for the benefit of people [21,22]. The increase in the consumption of this fruit has generated an increase in waste products, creating a great problem for farmers and companies dedicated to the export and import of the fruit [23,24]. The use of organic waste, mainly fruit and vegetable waste, as fuel creates a great opportunity for governments and companies to reuse their own waste, even more so if this technology can be scaled for large quantities.…”

Section: Introductionmentioning

confidence: 99%

Impact of Dragon Fruit Waste in Microbial Fuel Cells to Generate Friendly Electric Energy

et al. 2023

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Pollution generated by the misuse of large amounts of fruit and vegetable waste has become a major environmental and social problem for developing countries due to the absence of specialized collection centers for this type of waste. This research aims to generate electricity in an eco-friendly way using red dragon fruit (pitahaya) waste as the fuel in single-chamber microbial fuel cells on a laboratory scale using zinc and copper electrodes. It was possible to generate voltage and current peaks of 0.46 ± 0.03 V and 2.86 ± 0.07 mA, respectively, with an optimum operating pH of 4.22 ± 0.09 and an electrical conductivity of 175.86 ± 4.72 mS/cm at 8 °Brix until the tenth day of monitoring. An internal resistance of 75.58 ± 5.89 Ω was also calculated with a maximum power density of 304.33 ± 16.51 mW/cm2 at a current density of 5.06 A/cm2, while the FTIR spectra showed a decrease in the initial compounds and endings, especially at the 3331 cm−1 peaks of the O–H bonds. Finally, the yeast-like fungus Geotrichum candidum was molecularly identified (99.59%). This research will provide great opportunities for the generation of renewable energy using biomass as fuel through electronic devices with great potential to generate electricity.

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Use of Pineapple Waste as Fuel in Microbial Fuel Cell for the Generation of Bioelectricity

Cited by 16 publications

References 64 publications

Green Energy Generated in Single-Chamber Microbial Fuel Cells Using Tomato Waste

Green Energy Generated in Single-Chamber Microbial Fuel Cells Using Tomato Waste

Use of Tangerine Waste as Fuel for the Generation of Electric Current

Impact of Dragon Fruit Waste in Microbial Fuel Cells to Generate Friendly Electric Energy

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