Dynamic Phase Alignment in Inertial Alfven Turbulence

Abstract

In weakly-collisional plasma environments with sufficiently low electron beta, Alfv\'enic turbulence transforms into inertial Alfv\'enic turbulence at scales below the electron skin-depth, k de 1. We argue that, in inertial Alfv\'enic turbulence, both energy and generalized kinetic helicity exhibit direct cascades. We demonstrate that the two cascades are compatible due to the existence of a strong scale-dependence of the phase alignment angle between velocity and magnetic field fluctuations, with the phase alignment angle scaling as αk k-1. The kinetic and magnetic energy spectra scale as k-5/3 and k-11/3, respectively. As a result of the dual direct cascade, the generalized-helicity spectrum scales as k-5/3, implying progressive balancing of the turbulence as the cascade proceeds to smaller scales in the k de 1 range. Turbulent eddies exhibit a phase-space anisotropy k k5/3, consistent with critically-balanced inertial Alfv\'en fluctuations. Our results may be applicable to a variety of geophysical, space, and astrophysical environments, including the Earth's magnetosheath and ionosphere, solar corona, non-relativistic pair plasmas, as well as to strongly rotating non-ionized fluids.