Evidence for Bures--Wasserstein Boundary Dynamics in the Living Human Brain

TL;DR

This paper explores how boundary transitions in substrate covariance flow on the Bures--Wasserstein manifold can be indirectly detected in living human brain spin probe experiments through cross-mode transfer effects.

Contribution

It derives a boundary-conditioned transfer theorem showing how substrate boundary transitions influence spin dynamics via cross-mode transfer in brain imaging.

Findings

Boundary transitions induce detectable cross-mode correlations in spin probes.

Transfer acts through an additive cross-diffusion channel, leaving conventional NMR observables unchanged.

Double-quantum SU(1,1) sector is the dominant recipient of boundary-induced transfer.

Abstract

When substrate-constrained covariance flow on the Bures--Wasserstein manifold reaches the Williamson boundary, single-mode compression saturates and further admissible covariance evolution is forced into the cross-mode complement. This paper derives how that substrate boundary transition becomes experimentally visible in an embedded spin probe in the living human brain. We formulate a boundary-conditioned transfer theorem: when the substrate enters the deep boundary regime in a coupled mode, the boundary-selected cross-mode continuation of substrate covariance flow enters the reduced spin dynamics as a nonzero inter-spin correlation block. The spin probe does not inherit the substrate boundary as a state; it detects the boundary indirectly through the transferred cross-mode sector of the reduced dynamics. To leading order, this transfer is selective: it acts through an additive cross-diffusion channel while leaving conventional single-mode NMR observables such as \(T_1\), \(T_2\), linewidths, and the ordinary single-quantum response dominated by the thermal background. Projecting the induced spin cross-mode structure into the two-spin algebra, we argue that the experimentally relevant dominant recipient is the double-quantum SU(1,1) pair sector rather than the compact zero-quantum SU(2) exchange sector. We then derive the coherence-transfer pathway through which this double-quantum pair coherence is converted into a detectable signal by the \(45^\circ\)--gradient--\(45^\circ\) readout block.