Universal non-thermal power-law distribution functions from the self-consistent evolution of collisionless electrostatic plasmas

Abstract

Distribution functions of collisionless systems are known to show non-thermal power law tails. Interestingly, collisionless plasmas in various physical scenarios, (e.g., the ion population of the solar wind) feature a v-5 tail in the velocity (v) distribution, whose origin has been a long-standing mystery. We show this power law tail to be a natural outcome of the self-consistent collisionless relaxation of driven electrostatic plasmas. We perform a quasilinear analysis of the perturbed Vlasov-Poisson equations to show that the coarse-grained mean distribution function (DF), f0, follows a quasilinear diffusion equation with a diffusion coefficient D(v) that depends on v through the plasma dielectric constant. If the plasma is isotropically forced on scales much larger than the Debye length with a white noise-like electric field, then D(v) v4 for σ<v<ωP/k, with σ the thermal velocity, ωP the plasma frequency and k the maximum wavenumber of the perturbation; the corresponding f0, in the quasi-steady state, develops a v-(d+2) tail in d dimensions (v-5 tail in 3D), while the energy (E) distribution develops an E-2 tail irrespective of the dimensionality of space. Any redness of the noise only alters the scaling in the high v end. Non-resonant particles moving slower than the phase-velocity of the plasma waves (ωP/k) experience a Debye-screened electric field, and significantly less (power law suppressed) acceleration than the near-resonant particles. Thus, a Maxwellian DF develops a power law tail. The Maxwellian core (v<σ) eventually also heats up, but over a much longer timescale than that over which the tail forms. We definitively show that self-consistency (ignored in test-particle treatments) is crucial for the development of the universal v-5 tail.