Linear-wave bound on electromagnetic energy equipartition at sub-electron scales in non-relativistic plasmas

Abstract

Recent Magnetospheric Multiscale (MMS) observations report approximate equality between electric and magnetic field energy spectral densities, 0 P[δ E]/2 ≈ P[δ B]/(2μ0), at sub-electron scales in reconnection-driven magnetotail turbulence, interpreted as relaxation toward thermodynamic equilibrium. We derive the electric-to-magnetic energy ratio from the linear polarization of kinetic Alfv\'en waves and whistler-mode waves in the two-fluid framework and show that it saturates at R∞=(VA/c)2(mi/me)(βe/2) deep in the sub-electron regime. Setting R∞=1 yields the universal threshold VA/c 2/[(mi/me)βe], which no non-relativistic space plasma satisfies. For typical magnetotail parameters, R∞≈ 2× 10-3, approximately 500 times below the observed value, a discrepancy rooted in the non-relativistic ordering (VA/c)2 1. Noise-floor estimates show that Search Coil Magnetometer and Electric Double Probe sensitivity convergence produces a spurious apparent equipartition throughout this regime. The observed equality likely reflects nonlinear dynamics, incoherent superposition of electromagnetic and electrostatic fluctuations, or instrumental noise contamination.