Theoretical mechanism to breakdown of photonic structure to design a micro PV panel

• Main Author: Md. Faruque Hossain
• Format: Article
• Language: English
• Published: Elsevier 2019-11-01
• Series: Energy Reports
• Online Access: http://www.sciencedirect.com/science/article/pii/S2352484718303433

The photon structure has been modeled and reconstructed to design and micro PV (photovoltaic) panel. Bose–Einstein photondistribution theory recommends that under low-temperature conditions, photonic-band-gap state photons are locally induced and remain in a steady condition due to long-lived equilibrium particles known as discrete energy state photons. I therefore assume that once a photon is in a thrilling relativistic thermal condition, it is not going to comply with Bose–Einstein discrete energy state theory. Owing to the highest relativistic thermal conditions, the photonic band gap volume is going to be naturally raised in its vicinity and the discrete energy state photon is going to be agitated with the highest relativistic thermal fluctuations. Therefore, the Bose–Einstein photonic dormant state is going to be broken down in its region and thus generate numerous photons. Simply, a single discrete energy state photon will be converted from the crossover phenomenon equilibrium state to a non-equilibrium state with the aim of exponentially generating numerous photons, here known as Hossain nonequilibrium photons ( HnP−). Computations disclose the fact that in a situation where only 0.00008 percent of a building’s external skin curtain wall is applied as a micro PV panel of converting Bose–Einstein equilibrium photons into HnP−, it is going to generate sufficient clean energy that satisfies the building’s total energy demand. Keywords: Clean energy conversion, Bose–Einstein photonic structure, Non-equilibrium photon production, Extreme relativistic condition and thermal fluctuation