The Hermitian inner product selects the time axis, the Born rule measures it
Abstract
The correspondence between 2× 2 Hermitian matrices and Minkowski 4-vectors recovers Lorentzian symmetries from the internal degrees of freedom of a qubit, with no reference to an external spacetime. Recent work characterises the resulting Lorentz invariants and leaves the mechanism of emergence -- what singles out a time direction -- as an explicit open question. We give an elementary answer and, in doing so, correct a natural misattribution. The bare spin space (C2,) is SL(2,C)-symmetric and singles out no axis; so is the null cone it generates. What selects a future-timelike axis is the choice of a Hermitian inner product, equivalently a positive reference form σ0: this choice -- made in passing from a normed space to a Hilbert space, before any probability is assigned -- reduces SL(2,C) to its maximal compact SU(2), the stabiliser of σ0. The Born rule enters one level later: ξ ξ = tr(σ0 \, ξξ) is the projection of the state's null vector onto σ0, i.e. its energy in that frame, and under a boost it rescales as a Doppler shift. Thus the Hilbert structure selects the axis; the Born rule is where that axis becomes a measurable energy and where the frame-dependence of ψ2 becomes empirical. The ingredients are classical; what we add is their identification as the mechanism the recent programme leaves open, with the symmetry-breaking step located precisely. This is a kinematic identification of that step, not a dynamical account of why a particular axis is selected. We close by handing back the many-qubit case, where the datum is a tuple of such choices.
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