We introduce Quantum Temporal Dualism (QTD), a framework that promotes time to a pair of noncommuting hermitian operators T+, T- satisfying T+, T- = iλI, where λ is a fundamental constant with dimensions of time-squared. We construct the minimal faithful representation of the resulting operator algebra on L2(ℝ2) via the Bopp shift, and embed quantum dynamics within an extended Hilbert space ℋext = ℋphys ⊗ L2(ℝ2) subject to a Hamiltonian constraint. We prove three principal results. First, the physical time S = T+ + T- and the clock discrepancy D = T+ - T- satisfy a genuine Heisenberg uncertainty relation ΔS ⋅ ΔD ≥ λ, establishing a fundamental trade-off between temporal precision and clock agreement. Second, solving the constraint and tracing over the algebraically inaccessible discrepancy variable yields emergent energy-basis decoherence governed by a factor Γ(ΔE) that is the Fourier transform of the discrepancy distribution—providing a first-principles algebraic derivation of the fundamental decoherence conjectured by Gambini, Porto, and Pullin (GPP) on semiclassical grounds. We show that this mechanism is robust under asymmetric constraints, and that non-separable initial conditions with energy-dependent clock drift reproduce the time-dependent (ΔE)2 ⋅ t scaling of GPP decoherence. Third, the temporal sector admits a Fock space decomposition with discrete quantum numbers labeling temporal phase-space area. Standard quantum mechanics is recovered exactly in the limit λ → 0. We ground the abstract operators in a concrete minisuperspace cosmological model where T+ and T- correspond to matter and geometry clocks, analyze the relationship to Page–Wootters, Bars' two-time physics, and Moyal mechanics, demonstrate consistency with all known experimental constraints, and identify the framework's limitations and open questions.
Dakota Robert Baber (Tue,) studied this question.
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