Transforming dark photons into sustainable energy

Abstract

To produce energy from dark photons γ−, colliding it with Higgs boson particle BR(H → γγ−) under extreme relativistic conditions (ERCs) has been proposed. The Higgs boson BR(H → γγ−) gets excited at extreme relativistic conditions and its quantum field has an extremely short-range weak force which can create electromagnetic field. Thus, it has been assumed that the induction of an electrically charged particle dark photon γ− (non-energy level photon), into these extreme relativistic conditions will create an energy level photon, here named the Hossain dark photon (HDP). To confirm this HDP formation via a dark photon quantum interaction with a Higgs boson particle BR(H → γγ−), a series of mathematical modeling tests using MATLAB software has been performed. Interestingly, these mathematical models revealed that the presence of extra relativistic conditions does transform the dark photon γ− into an HDP for N_{text{eff}} = 4.08_{ - 0.68}^{ + 0.71} at a 95% confidence limit considering the parameters of c_{text{eff}}^{2} = 0.312 pm 0.026 and c_{text{vis}}^{2} = 0.29 _{ - 0.16}^{ + 0.21}, respectively. Thereafter, the feasible HDP photon dynamics is also modeled using the atomic spectra contour maps of the Hamiltonian (H = mathop sum nolimits omega_{ci} a_{i}^{dag } a_{i} + sumnolimits_{K} {omega_{k } b_{k}^{dag } b_{k} } + sumnolimits_{ik} {(V_{ik} a^{dag } b_{k} + V_{ik}^{*} b_{k}^{dag } a_{i} )}) which suggested that formation of HDP by a Higgs boson [BR(H → γγ−] particle reaction under extreme relativistic conditions does form high energy level particle to produce electricity.