This work develops a principle theory connecting the topology of the time-direction structure of spacetime to observable quantum dynamics. Following Einstein's principle-theory methodology, we establish three foundational principles and derive all consequences from them without phenomenological assumptions. The first principle identifies the time-direction field as a principal bundle whose topology is characterized by the first Stiefel-Whitney class. The second principle states that when this topological class is non-trivial, the resulting holonomy produces spin-dependent phases observable in quantum dynamics. The third principle posits that the observability of these topological effects is governed by competition between the topological holonomy rate and environmental decoherence. From these three principles alone, we derive: a spin-dependent topological phase that is zero for bosons and maximal for fermions; the Lindblad equation for temporal direction dynamics from the quantum field theory path integral via the Feynman-Vernon influence functional; the temporal direction coherence formula where mass dependence enters exclusively through known decoherence physics; a first-principles upper bound on the holonomy rate from cosmological constraints; five internal consistency theorems; and parameter-independent predictions, most notably the infinite fermion-boson temporal decoherence ratio. All results are compatible with standard quantum field theory, which is recovered in the limit where the topological rate vanishes. The framework provides a structural, rather than merely contingent, basis for the arrow of time, complementing but not replacing the Past Hypothesis.
Fangyuan Hao (Mon,) studied this question.