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Civil-Comp Conferences
ISSN 2753-3239 CCC: 2
PROCEEDINGS OF THE ELEVENTH INTERNATIONAL CONFERENCE ON ENGINEERING COMPUTATIONAL TECHNOLOGY Edited by: B.H.V. Topping and P. Iványi
Paper 14.3
Application of Computer Modelling in Building Design to Breakdown the Bose-Einstein Non-Energy State Photonic Structure into Energy State Photon to Produce Clean Energy M.F. Hossain
College of Architecture and Construction Management, Kennesaw State University, Marietta, USA M.F. Hossain, "Application of Computer Modelling in Building
Design to Breakdown the Bose-Einstein Non-Energy State Photonic Structure into Energy State
Photon to Produce Clean Energy", in B.H.V. Topping, P. Iványi, (Editors), "Proceedings of the Eleventh International Conference on Engineering Computational Technology", Civil-Comp Press, Edinburgh, UK,
Online volume: CCC 2, Paper 14.3, 2022, doi:10.4203/ccc.2.14.3
Keywords: Bose-Einstein dormant photons, dormant photon remodeling, photonic band gap activation, photon structure breakdown, clean energy production.
Abstract
Bose-Einstein photon distribution theory is being remodelled to convert a single photon into multiple (81) photons by the activation of this discrete photonic bandgap (PBG) at the nanoscale to transform this photon into energy state photons. Subsequently, the quantum dynamics of these dormant photons are being activated under the condition of extreme point break photon dynamics state since this adverse condition will not obey the Bose-Einstein photon distribution theory and thus, the dormant state photon will be broken down, here named as Hossain nonequilibrium photons (HnP-). To calculate the energy conversion from this HnP-, a detailed model considering a single diode electricity transformation mechanism has been performed which suggested if only a mere 0.33 m2 of a building’s curtain wall is designed as an extreme PV panel, it will trap sufficient solar irradiance to transform enough electricity to meet the net energy demand for a building of 32-meter x 31-meter footprint with the height of 30 meters.
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