Your search keyword '"Otiniano, Nélida Milly"' showing total 6 results

1. Electricity Generation and Plastic Waste Reduction Using the Fungus Paecilomyces as a Biodegrader in Microbial Fuel Cells.

Author

Segundo, Rojas-Flores, Magaly, De La Cruz-Noriega, Otiniano, Nélida Milly, Luis, Cabanillas-Chirinos, and Angelats-Silva, Luis M.

Abstract

The great utility that plastics generate for society has generated a large amount of waste, producing tons of garbage from this material that damages the ecosystem, human health, and farmland. Likewise, the issue of the absence of electricity in low-income areas is critical for society. This research proposes a novel solution to simultaneously solve these two problems, which, through single-chamber microbial fuel cells, introduce plastic waste and the fungus Paecilomyces. The microbial fuel cells (MFCs) showed a maximum electric current of 0.547 ± 0.185 mA with a peak voltage of 0.575 ± 0.106 V on day 36; on this day, the MFCs operated with a pH of 6.524 ± 0.360 and electrical conductivity of 264.847 ± 6.395 mS/cm. These results demonstrate the potential of this system to generate electricity from plastic waste, addressing the issue of electricity scarcity in low-income areas. The chemical oxygen demand was also reduced by 85.47%, indicating the system's ability to degrade plastic waste. The power density calculated on day 36 was 0.0624 ± 0.0053 mW/cm2 at a current density of 0.0052 mA/cm2 and an internal resistance of 55.254 ± 7.583 Ω. The reducing action of the fungus on the plastic was demonstrated in the FTIR transmittance spectrum because the characteristic peaks (3378, 2854–2911, 1642, 1472, and 720 cm−1) of the plastic suffered reductions in the final state, and the micrographs of the plastic surfaces showed the lifting of layers and the formation of irregular structures and a decrease in the thickness of the plastic sample of 139.66 ± 4.19 µm. [ABSTRACT FROM AUTHOR]

Published

2024

2. Reducing Plastic Waste and Generating Bioelectricity Simultaneously through Fuel Cells Using the Fungus Pleurotus ostreatus.

Author

Segundo, Rojas-Flores, Magaly, De La Cruz-Noriega, Luis, Cabanillas-Chirinos, Otiniano, Nélida Milly, Soto-Deza, Nancy, and Terrones-Rodríguez, Nicole

Abstract

Plastic waste, a persistent and escalating issue, and the high costs of installing electric power, particularly in remote areas, have become pressing concerns for governments. This research proposes a novel method for generating electric power from sugarcane bagasse waste and reducing plastic waste. The key to this method is the use of the fungus Pleurotus ostreatus in microbial fuel cells. Microbial fuel cells (MFCs) demonstrated their effectiveness by generating peaks of electric current (4.325 ± 0.261 mA) and voltage (0.427 ± 0.031 V) on day twenty-six, with a pH of 5.539 ± 0.278. The peak electrical conductivity of the substrate was 130.574 ± 4.981 mS/cm. The MFCs were able to reduce the chemical oxygen demand by 83%, showing a maximum power density of 86.316 ± 4.724 mW/cm2 and an internal resistance of 37.384 ± 62.522 Ω. The infrared spectra of the plastic samples showed a decrease in the peaks 2850–2920, 1470, and 720 cm−1, which are more characteristic of plastic, demonstrating the action of the Pleurotus ostreatus fungus on the plastic samples. Also, the micrographs taken by SEM showed the reduction in the thickness of the plastic film by 54.06 µm and the formation of microstructures on the surface, such as pores and raised layers of the sample used. [ABSTRACT FROM AUTHOR]

Published

2024

3. Sustainable Use of the Fungus Aspergillus sp. to Simultaneously Generate Electricity and Reduce Plastic through Microbial Fuel Cells.

Author

Rojas-Flores, Segundo, De La Cruz-Noriega, Magaly, Otiniano, Nélida Milly, and Cabanillas-Chirinos, Luis

Abstract

The improper disposal of plastic waste has become a significant problem, with only a small amount recycled and the rest ending up in landfills or being burned, leading to environmental pollution. In addition, the cost of electric energy has risen by over 100% in the last 20 years, making it unaffordable for remote areas to access this service due to high installation costs, leaving people living far from major cities without electricity. This study proposes an innovative solution to these issues using microbial fuel cell (MFC) technology to simultaneously reduce plastic waste and generate electric energy by utilizing the fungus Aspergillus sp. As a substrate for 45 days. The MFCs reached maximum values of 0.572 ± 0.024 V and 3.608 ± 0.249 mA of voltage and electric current on the thirty-first day, with the substrate operating at a pH of 6.57 ± 0.27 and an electrical conductivity of 257.12 ± 20.9 mS/cm. Furthermore, it was possible to reduce the chemical oxygen demand by 73.77% over the 45 days of MFC operation, while the recorded internal resistance was 27.417 ± 9.810 Ω, indicating a power density of 0.124 ± 0.006 mW/cm2. The initial and final transmittance spectra, obtained using FTIR (Fourier Transform Infrared), showed the characteristic peaks of polyethylene (plastic), with a noticeable reduction in the final spectrum, particularly in the vibration of the C-H compound. After 45 days of fungus operation, the plastic surface used as a sample exhibited perforations and cracks, resulting in a thickness reduction of 313.56 µm. This research represents an initial step in using fungi for plastic reduction and electric energy generation in an alternative and sustainable manner. [ABSTRACT FROM AUTHOR]

Published

2024

4. Obtaining Sustainable Electrical Energy from Pepper Waste.

Author

Segundo, Rojas-Flores, Magaly, De La Cruz-Noriega, Luis, Cabanillas-Chirinos, Otiniano, Nélida Milly, Soto-Deza, Nancy, Terrones-Rodriguez, Nicole, and Mayra, De La Cruz-Cerquin

Abstract

Currently, two significant problems involve the government, population, and environment: the accelerated increase in organic waste and the need to replace conventional energy with environmentally sustainable energy. The sustainable use of organic waste is being intensely investigated to generate energy plants that produce alternative sustainable electrical energy beneficial to the population at a low cost. The novelty of this research is given by the use of pepper waste as fuel in the generation of bioelectricity, giving added value to these types of waste, benefiting farmers and companies dedicated to the export and import of these fruits, because they will be able to generate their own electrical energy using their own waste at a lower cost. For this reason, this research uses pepper waste as fuel in single-chamber microbial fuel cells manufactured at a low cost as its primary objective. The maximum values of the electric current (5.118 ± 0.065 mA) and electric potential (1.018 ± 0.101 V) were shown on the fourteenth day, with an optimal operating pH of 7.141 ± 0.134 and electrical conductivity of 112.846 ± 4.888 mS/cm. Likewise, a reduction in the COD was observed from 1210.15 ± 0.89 mg/L to 190.36 ± 16.58 mg/L in the 35 days of monitoring and with a maximum ORP of 426.995 ± 8.615 mV, whose internal resistance was 33.541 ± 2.471 Ω. The peak power density was 154.142 ± 8.151 mW/cm2 at a current density of 4.834 A/cm2, and the Rossellomorea marisflavi strain was identified with 99.57% identity. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

Segundo, Rojas-Flores, Benites, Santiago M., De La Cruz-Noriega, Magaly, Vives-Garnique, Juan, Otiniano, Nélida Milly, Rojas-Villacorta, Walter, Gallozzo-Cardenas, Moisés, Delfín-Narciso, Daniel, and Díaz, Félix

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2023

6. Effect of Inoculum Concentration on the Degradation of Diesel 2 by a Microbial Consortium.

Author

Otiniano, Nélida Milly, Rojas-Villacorta, Walter, De La Cruz-Noriega, Magaly, Lora-Cahuas, Carmen, Mendoza-Villanueva, Karol, Benites, Santiago M., Gallozzo-Cardenas, Moises, and Rojas-Flores, Segundo

Abstract

The objective was to determine the effect of inoculum concentration on the degradation of Diesel 2 by a microbial consortium called BIOT.PD001. For this, five systems were designed (in triplicate), which Contained Davis Minimum Medium, 5% Diesel 2 as a carbon source, and a suspension of the microbial consortium BIOT.PD001 (9 × 108 cells/mL) in concentrations of 2, 4, 6, 8, and 10% of the final volume. The monitoring of the degradation of Diesel 2 was carried out indirectly through the bacterial counts by the plate count method, the Biochemical Oxygen Demand (BOD5) by the Winkler Method modified according to Alsterberg, and the concentration of total fats by Gerber's method. The retention time was 15 days. It was observed that the percentage of efficiency of the process increases as the concentration of inoculum increases, obtaining the highest percentage of efficiency (94.77%) when using 10% of inoculum (v/v), while when using inoculum concentrations of 2 and 4% (v/v), the efficiency percentages are the lowest, (68.4 and 66.6%, respectively). On the other hand, the variance analysis indicated that there is a significant difference between the averages of these values. The regression analysis indicated that the inoculum concentration significantly affects the efficiency of Diesel 2 degradation and that this is 86% explained by a linear regression model. There is a linear relationship between the inoculum concentration of the BIOT.PD001 microbial consortium and the BOD5 tend to decrease as a function of time. It is concluded that the inoculum concentration significantly affects the efficiency of the degradation of Diesel 2 by the BIOT.PD001 consortium. [ABSTRACT FROM AUTHOR]

Published

2022