| Summary: | The Bose–Einstein photonic structure has been deconstructed and modelled using the MATLAB software to design a micro photovoltaic (PV) panel for producing clean energy. Bose–Einstein photon distribution theory suggests that under low-temperature conditions, photonic-band-gap state photons are induced locally and remain steady as long-lived equilibrium particles called discrete energy state photons. Thus, I assume that once a photon is in an extreme relativistic thermal condition, it will not obey Bose–Einstein discrete energy state theory. The photonic band gap volume will be naturally increased within its vicinity as a result of the extreme relativistic thermal conditions, and the discrete energy state photon will be agitated by extreme relativistic thermal fluctuations. Consequently, the Bose–Einstein photonic dormant state will be broken down within its region and will create a multiple number of photons. Simply, a single discrete energy state photon will be transformed from the crossover phenomenon equilibrium state to a non-equilibrium state to exponentially create multiple photons, here named Hossain nonequilibrium photons ( HnP−). Calculations reveal that if only 0.00008% of a building’s exterior skin curtain wall is used as a micro PV panel to transform Bose–Einstein equilibrium photons into HnP−, it will produce enough clean energy to satisfy the total energy demand of a building. Keywords: Bose–Einstein photonic structure, Extreme relativistic condition, Thermal fluctuation, Non-equilibrium photon production, And clean energy conversion
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