Restoring a Missing Meta-Symmetry of Quantum Mechanics

Abstract

In conventional quantum mechanics, all unitary evolution takes place within the space-time Hilbert space Hxt=L2( Mxt), with time as the sole evolution parameter. The momentum-energy representation φ(k,E) is treated merely as a Fourier re-expression of the same state-kinematically equivalent but dynamically inert. Here we restore the fundamental symmetry between the conjugate pairs (x,t) and (k,E) by extending the quantum theory to an enlarged Hilbert space Htotal = Hxt HkE, within which the momentum-energy sector HkE=L2( MkE) carries its own autonomous unitary evolution generated by a self-adjoint operator T. The resulting structure establishes a meta-symmetry: a symmetry between two conjugate dynamical projections of a single global quantum state. It produces a dual-manifold geometry in which each domain is locally complete yet globally open, with divergent limits in one mapping onto extended regions in the other. Remarkably, the dual-manifold symmetry alone reproduces both the uniform dark-energy background and the exponential boundary mapping near black-hole horizons that underlies Hawking radiation. This framework thus opens a quantum-theoretic route to cosmological phenomena that are ordinarily treated within general relativity.

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