What is time? Every physical theory must answer this question, and the answer it gives determines everything else. Newtonian mechanics postulates absolute time flowing uniformly “without relation to anything external.” General relativity replaces this with proper time — arc length along a worldline in a Lorentzian manifold — but the manifold itself is still postulated as external input. Category τ derives time from structure.

In Book IV, proto-time was defined as the ρ-iteration depth along the refinement tower (IV.D05): the natural number t_p(α_n) = n. Proto-time is discrete, absolute, and structural — but it is not yet physical time. Physical time requires a metric: a way to assign duration to intervals, to compare “how long” one process takes relative to another. This chapter bridges the gap.

The base circle τ¹ — the projection of τ³ onto its {α, π} component — carries a natural metric structure inherited from the profinite topology. Proper time is geodesic arc length along τ¹ (the relevant definition, V.D14). Each step of the α-orbit — each application of ρ — is one α-tick (the relevant definition, V.D13), and the accumulated arc length up to tick n is the physical time t(n).

The arrow of time is the generative direction of the α-orbit (Proposition [prop:ch04-arrow-orbit], V.P03) — not a thermodynamic accident but a structural feature of the kernel axioms. Causality is orbit ordering (the relevant theorem, V.T07): if α_m precedes α_n in the refinement tower, then event m causally precedes event n. And physical time is bounded (the relevant theorem, V.T08): the base circle is compact, the universe has finite temporal extent from α_a (beginning) to α_o (end).