Quantum-Distributed Metastable Control Architecture for the Linear Fusion Magnetic Mirror Reactor (LFMR-Q): Achieving Algorithmic Precedence over Kinetic Instabilities

Linear magnetic mirror fusion devices are intrinsically limited by microsecond-scale ki-netic instabilities, including firehose, mirror, and Drift-Cyclotron Loss-Cone (DCLC) modes.This paper introduces the LFMR-Q architecture, a closed-loop feedback system utilizingfemtosecond laser diagnostics stabilized via 2D Position Sensitive Detectors (PSD) and Quad-rant Photodiodes (QPD). By coupling these diagnostics to a remote Quantum Computingunit through an entanglement-based quantum communication link, we propose a frameworkfor “algorithmic precedence.” This allows for the predictive stabilization of plasma within ametastable operating manifold, preempting macroscopic confinement collapse.