Improved collection of photogenerated current using bi-metal nanoparticles.
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Date
2024
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Abstract
The energy demand has been continuously growing owing to the shortage of sources of traditional energy (such as fossil fuels), due to the growing population of the world, and increased industrialization, which prompted the need for more energy. However renewable energy (such as photovoltaics) has attained attention due to its reliance on the infinite energy source (sun) which provides an hour long energy flow that fulfil the yearly energy of the glob. Not only that, renewable energy sources offer clean energy, that is meant to contribute to decarbonization in the future and reduce environmental changes. Solar cell materials that can effectively capture photons and conduct charges are continuously investigated for the last six decades. Contrarily to silicon based solar cells, organic solar cells are among the most promising solar cells in terms of offering cheap device fabrication, flexibility, high absorption, etc. However, these solar cells still suffer from low efficiency compared to traditional silicon solar cells due to poor absorption, low mobility, and poor stability. Numerous strategies have been employed to improve the efficiency of OSC devices, these include Ternary OScs, Tandem OSCs, and the inclusion of nanoparticles in OSC devices. Nanoparticles remain the best candidate to feature in OSC devices because Tandem OSCs require multi-absorber layers which leads to high device cost, whereas nanoparticles can be produced at a small scale and still offer good results. This study takes advantage of the features offered by the nanoparticles and uses them to investigate the effect of Nickel doped with cobalt bi-metal nanoparticles(Ni/Co BMNPs) in the PEDOT:PSS buffer layers of the P3HT: PCBM-based devices. Solar cells were successfully fabricated with four different concentrations of Ni/Co BMNPs as 0.05 %(0.5 mg), 0.15 %(1.5 mg), and 0.25 %(2.5 mg). Significant improvements were achieved for the 0:05% with the Fill factor of 58:52 %, and current density of 15.31 mA/cm2, and maximum efficiency of 5:05 % which displayed 67:8 % improvement from the undoped device. The investigation was further conducted by simulation program called SCAPS to confirm the contribution of the metal nanoparticles on the device performance. The results were reproduced in SCAPS where the energy band gap of the P3HT:PCBM and the shallow conduction density of electrons of the PEDO:PSS were simultaneously varied. All results are comparable with the experimental results and found to be similar. The device that was made to mimic the 0:05 % device produced a FF of 57:76 %, Jsc of 15.76 mA/cm2, and maximum efficiency of 5:76 % which displayed 88 % improvement from the undoped device. This study further provides factors that contributed to the high/low device performance due to the inclusion of the BMNPs in the OSC device and some of the necessary background and theory are provided to support these findings.
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Masters Degree. University of KwaZulu-Natal, Pietermaritzburg.
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https://doi.org/10.29086/10413/23102