Performance evaluation of the novel 3D-printed aquatic plant-microbial fuel cell assembly with Eichhornia crassipes

Malinis, Mel Patrick D.; Velasco, Herna Jones F; Pamintuan, Kristopher Ray

doi:10.14710/ijred.2023.53222

Cited by 3 publications

(1 citation statement)

References 41 publications

(27 reference statements)

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“…MFCs effectively produce electricity from various sources, including natural organic matter, complex organic waste, and sustainable biomass. In addition, it can be integrated with wastewater treatment applications (Oliveira et al 2013) and with plant microbial fuel cells (Palmero and Pamintuan 2023;Malinis et al 2023). Electrons resulting from microbial-catalyzed biochemical reactions flow to the anode.…”

Section: Introductionmentioning

confidence: 99%

Enhancing microbial fuel cell performance with carbon powder electrode modifications for low-power sensors modules

Al-badani,

Chong,

Lim

2023

Int. J. Renew. Energy Dev.

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Microbial Fuel Cell (MFC) is a promising technology for harnessing energy from organic compounds. However, the low power generation of MFCs remains a significant challenge that hinders their commercial viability. In this study, we reported three distinct modifications to the stainless-steel mesh (SSM), carbon cloth, and carbon felt electrodes using carbon powder (CP), a mixture of CP and ferrum, and a blend of CP with sodium citrate and ethanol. The MFC equipped with an SSM and CP anode showed a notable power density of 1046.89 mW.m-2. In comparison, the bare SSM anode achieved a maximum power density of 145.8 mW m-2. Remarkably, the 3D-modified SSM with a CP anode (3D-SSM-CP) MFC exhibited a substantial breakthrough, attaining a maximum power density of 1417.07 mW m-2. This achievement signifies a significant advancement over the performance of the unaltered SSM anode, underscoring the effectiveness of our modification approach. Subsequently, the 3D-SSM-CP electrode was integrated into single-chamber MFCs, which were used to power a LoRaWAN IoT device through a power management system. The modification methods improved the MFC performance while involving low-cost and easy fabricating techniques. The results of this study are expected to contribute to improving MFC's performance, bringing them closer to becoming a practical source of renewable energy.

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Section: Introductionmentioning

confidence: 99%

Enhancing microbial fuel cell performance with carbon powder electrode modifications for low-power sensors modules

Al-badani,

Chong,

Lim

2023

Int. J. Renew. Energy Dev.

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Advances in amelioration of air pollution using plants and associated microbes: An outlook on phytoremediation and other plant-based technologies

James,

Rene,

Bilyaminu

et al. 2024

Chemosphere

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Development of a 3D-printed spongy electrode design for microbial fuel cell (MFC) using gyroid lattice

Pamintuan,

Manga,

Balmes

2024

Int. J. Renew. Energy Dev.

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Microbial fuel cell technology addresses both issues in finding new ways to clean water systems while harnessing electricity. Several studies suggest that a single large-scale MFC is proven to be inefficient and expensive. Therefore, producing small-scale MFCs is focused on investigation to provide an efficient system and cost-effective approach. This study used 3D-printed MFCs using a spongy electrode design to produce a modern approach to modifying electrode capacity in energy generation. Furthermore, the study identifies the electrical conductivity of the spongy electrode by determining the voltage generated and power density by stacked MFCs in series, parallel, and hybrid configurations. The MFCs generate a maximum voltage of 633 mV and a current of 14.22 . One way to reduce the effects of voltage reversal in the MFC system is the application of hybrid connection circuits. Parallel-series hybrid connection possesses stable voltage generation of 250−300 𝑚𝑉 with the highest current generation of 115.20 𝜇𝐴. At the same time, the Series-Parallel Connection generates the highest voltage and current of 259 mV and 30 , respectively. The spongy electrode design and hybrid connection produced a maximum power and current density of 29.30 μW⁄m2 and 279.41 μA⁄m2 obtained from a different connection of pure parallel and 28P-2S hybrid connection. Furthermore, water quality parameters were examined (pH, TDS, ORP, and COD), that the MFCs design is efficient in wastewater treatment, with a %COD removal of 95.24% efficiency, reduced ORP from +48.00 mV to -7.00 mV, and the TDS concentration from 270 ppm to 239 ppm.

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Performance evaluation of the novel 3D-printed aquatic plant-microbial fuel cell assembly with Eichhornia crassipes

Cited by 3 publications

References 41 publications

Enhancing microbial fuel cell performance with carbon powder electrode modifications for low-power sensors modules

Enhancing microbial fuel cell performance with carbon powder electrode modifications for low-power sensors modules

Advances in amelioration of air pollution using plants and associated microbes: An outlook on phytoremediation and other plant-based technologies

Development of a 3D-printed spongy electrode design for microbial fuel cell (MFC) using gyroid lattice

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