Spontaneous Decoherence from Logarithmic Spectral Phase Deformations
Abstract
We examine a mechanism of spontaneous decoherence in which the generator of quantum dynamics is deformed to a logarithmically modified self-adjoint operator equation* Fβ(H) = H + β H HE* equation* for a positive self-adjoint Hamiltonian H and a fixed reference scale E* > 0. Dynamical phases acquire energy-dependent factors [-itβ E (E/E*)], whose rapid variation across the spectrum suppresses interference between distinct energies through a non-stationary-phase mechanism. Stationary-phase analysis shows that oscillatory contributions to amplitudes decay at least as O(1/|β|) when |β| is large. Since Fβ(H) is self-adjoint for every real β, the evolution operator Uβ(t) = [-itFβ(H)] is unitary. The kinematical structure of quantum mechanics -- Hilbert-space inner products, projection operators, the Born rule -- remains unchanged. Decoherence arises as suppression of interference terms in coarse-grained observables and decoherence functionals, not as norm loss or stochastic collapse. Physical motivation for logarithmic spectral deformations comes from clock imperfections, renormalization-group and effective-action corrections introducing E terms, and semiclassical gravity analyses with complex actions generating spectral factors involving (E/EP). The mechanism is illustrated with two-level systems, quartic oscillators, FRW minisuperspace models, and Schwarzschild-interior-type Hamiltonians. Current superconducting-qubit coherence times constrain |β| 10-5; trapped ions, NV centers, and cold atoms could strengthen this to |β| 10-8.
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