Photon energy amplification for the design of a micro PV panel

Hossain, Md. Faruque

doi:10.1002/er.4118

“…The current flow into the circuit cells which is determined by the functional mode of its P-N junction that is able to produce electricity by conducting the interconnection of series-parallel configuration of the circuit cell (34,47,52). Implementation of the standard single diode circuit cell, the function of Ns series and Np parallel connection in relation to current generation can be expressed as…”

Section: Bio Energymentioning

confidence: 99%

Green Technology: Transformation of Domestic Bio-Waste into Electricity Energy to Mitigate the Global Energy and Environmental Vulnerability

Hossain¹

2020

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Background Green Technology, a sustainable mechanism is being proposed to fulfill the complete need of energy for a building that can be created by the building itself by the transformation process of domestic biowaste into electricity energy in site.Results The results suggested that the transformation of domestic biowaste including human feces to execute into converting process into an anaerobic tank bioreactor (BR) in the cellar which can form biogas (CH4) by methanogenesis that can be converted into electricity energy to power the entire building. Besides, the discharged waste water in another detention tank can be conducted a complete treatment process of primary, secondary, tertiary and UV application to utilize it for gardening.Conclusions Implementation of this technology indeed shall be an inventive field of science where a building can form electricity by itself to complete its total energy need without any connection with the utility authorities which is benevolent to environment.

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“…Although several excellent works on perovskite solar cells (PSC) developed into a promising branch of renewable energy conversion have been conducted to increase up to 22.1% efficiency during the last several years, stabilizing them under the operating condition without compromising optimal optoelectronic properties remains challenging, and thus, this achievement is not satisfactory enough to trap solar energy massively for commercial use throughout the world (21,21). Thus, it has presented an unsurmountable challenge to date for commercial used solar energy globally with an attractive efficiency rate (4,19). Interestingly, recent studies revealed that pair-photon formation from a single one is doable via photon-photon collision of a single photon once implemented by high thermal conditions but difficult to demonstrate the potential applications of this energy commercially (1,5,9).…”

Section: Introductionmentioning

confidence: 99%

Splitting Photon into Pair Photons to Design a High-Performance Printable Solar Cell

Hossain

¹

2023

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The fine silicon printable solar cell is being layered up by a very thin complex photopolymer (chloro-trifluoro-ethylene vinyl ether fluoropolymer binder and dimethacrylic perfluoropolyether oligomer) to pave forming high temperature inside the solar cell to release gamma-ray to split single photon into pair-photons. Since the conservation of photon momentum are the principal constraints for this process of breakdown of photon particle, thus, all released conserved quantum numbers (photon to electron and positron, basic kinematics, and energy transfer) are being monitored during this pair-photon production by using PerkinElmer® Lambda 25 UV/Vis Spectrometer. Subsequently, the measurement of the required photon frequency (f), and wavelength (λ) to form these pair-photons by the induction of gamma-ray has also been determined to design high-performance solar cells. The results suggested that solar cells profoundly release the gamma-ray due to the presence of photopolymer which initiates high temperature inside the solar cell and pave the photon-photon collision to produce pair-photons from a single one. Subsequently, photon to electron and positron, its basic kinematics have also been monitored during this photon-photon interaction to determine the energy transfer to design high-performance solar cells.

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“…Thus, it has presented an unsurmountable challenge to date for commercial used solar energy globally with an attractive e ciency rate (4,19). Interestingly, recent studies revealed that pair-photon formation from a single one is doable via photon-photon collision of a single photon once implemented by high thermal conditions but di cult to demonstrate the potential applications of this energy commercially (1,5,9).…”

Section: Introductionmentioning

confidence: 99%

Splitting Photon into Pair Photons to Design a High-Performance Printable Solar Cell

Hossain

¹

2022

Preprint

Self Cite

0

View full text Add to dashboard Cite

The fine silicon printable solar cell is being layered up by a very thin complex photopolymer (chloro-trifluoro-ethylene vinyl ether fluoropolymer binder and dimethacrylic perfluoropolyether oligomer) to pave forming high temperature inside the solar cell to release gamma-ray to split single photon into pair-photons. Since the conservation of photon momentum are the principal constraints for this process of breakdown of photon particle, thus, all released conserved quantum numbers (photon to electron and positron, basic kinematics, and energy transfer) are being monitored during this pair-photon production by using PerkinElmer® Lambda 25 UV/Vis Spectrometer. Subsequently, the measurement of the required photon frequency (f), and wavelength (λ) to form these pair-photons by the induction of gamma-ray has also been determined to design high-performance solar cells. The results suggested that solar cells profoundly release the gamma-ray due to the presence of photopolymer which initiates high temperature inside the solar cell and pave the photon-photon collision to produce pair-photons from a single one. Subsequently, photon to electron and positron, its basic kinematics have also been monitored during this photon-photon interaction to determine the energy transfer to design high-performance solar cells.

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Photon energy amplification for the design of a micro PV panel

Cited by 22 publications

References 48 publications

Green Technology: Transformation of Domestic Bio-Waste into Electricity Energy to Mitigate the Global Energy and Environmental Vulnerability

Green Technology: Transformation of Domestic Bio-Waste into Electricity Energy to Mitigate the Global Energy and Environmental Vulnerability

Splitting Photon into Pair Photons to Design a High-Performance Printable Solar Cell

Splitting Photon into Pair Photons to Design a High-Performance Printable Solar Cell

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