A recent structural reinterpretation of gauge interfaces within the C-parity framework suggests a natural physical question concerning the effective inertial mass of Cooper pairs. In standard treatments, the London moment of a rotating superconductor probes the effective inertial mass of the superconducting carrier after relativistic, geometric, penetration-depth, and lattice-potential corrections have been included. We propose a flat-space effective ansatz in which the transition of a metal into a coherent BCS superconducting ground state may induce a residual carrier-level inertial susceptibility. The starting point is the algebraic separation, within the C-parity framework, between a C-even mass carrier and a C-odd/mixed operational electromagnetic readout channel. The superconducting transition reorganizes the charged degrees of freedom through which this electromagnetic readout channel is expressed. We therefore parametrize the effective Cooper-pair inertial mass as^₂=m^₀ (1+₂), m^₀ denotes the standard theoretical carrier mass after conventional corrections. We suggest that the natural microscopic small scalecontrolling the residual contribution is the BCS phase-space fraction /EF, leading to\ BBₓ₇₂EF. relation is intended as a flat-space, inertial, residual phenomenological parametrization, not as a gravitational derivation from curvature coupling.
Karim Daghbouche (Thu,) studied this question.
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