Submitted:
23 May 2022
Posted:
24 May 2022
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Abstract
There is no formal difference between particles and black holes. This formal similarity lies in the intersection of gravity and quantum theory; quantum gravity. Motivated by this similarity, `wave-black hole duality' is proposed, which requires having a proper energy-momentum tensor of spacetime itself. Such a tensor is then found as a consequence of `principle of minimum gravitational potential'; a principle that corrects the Schwarzschild metric and predicts extra periods in orbits of the planets. In search of the equation that governs changes of observables of spacetime, a novel Hamiltonian dynamics of a Pseudo-Riemannian manifold based on a vector Hamiltonian is adumbrated. The new Hamiltonian dynamics is then seen to be characterized by a new `tensor bracket' which enables one to finally find the analogue of Heisenberg equation for a `tensor observable' of spacetime.
Keywords:
Wave-black hole duality
; nonmetricity
; corrections to gravitational potential
; minimum gravitational potential
; geometry of implicit line elements
; corrected Schwarzschild metric
; energy-momentum tensor of spacetime
; wavefunction of a black hole
; Hamiltonian dynamics of a manifold
; tensor Poisson bracket
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