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

Abstract

Abstract 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.