Chronoscalar Corridor Transport Unifies Lithium Depletion, Directionally Selective Radiative Escape, Synodic Irradiance Beats, and Magnetic Ejection Geometry

Abstract

Stellar interiors manifest a persistent one-percent constraint across phenomena that standard models treat as unrelated: the slow destruction of lithium in young stars, the percent-level excess of solar radiative flux, the confinement of magnetic flux tubes into narrow kilogauss structures, and the delayed detonation of coronal mass ejections. These signatures, spanning more than ten orders of magnitude in scale, are unified here by a single geometric mechanism. Chronoscalar Field Theory (CFT) posits that the Universe contains an asymmetric time field T(xμ) whose primordial gradient ∇T and associated drift establish the arrow of time and the persistence of physical structure.text.21 This gradient is not a background parameter but a physical field whose eigenstructure imprints every plasma it permeates. In stellar interiors, the drift organizes the time field into narrow, quasi-one-dimensional defects known as chronoscalar corridors. These were first identified in the quantum sector as Gabriel Corridors governing entanglement connectivity, but their macroscopic manifestation in plasma provides a natural mechanism for transport suppression. Only a fraction Pcorr ≃ 10−2 of material trajectories sample these corridors, establishing a universal one-percent law of vertical transport. Lithium depletion, photon leakage, magnetic condensation, and eruptive destabilization all proceed at rates governed by the same geometric constraint. We

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