Cosmic-ray modulation: an ab initio approach
Abstract
A better understanding of cosmic-ray modulation
in the heliosphere can only be gained through a proper understanding
of the effects of turbulence on the diffusion and drift
of cosmic rays. We present an ab initio model for cosmic-ray
modulation, incorporating for the first time the results yielded
by a two-component turbulence transport model. This model
is solved for periods of minimum solar activity, utilizing
boundary values chosen so that model results are in fair to
good agreement with spacecraft observations of turbulence
quantities, not only in the solar ecliptic plane but also along
the out-of-ecliptic trajectory of the Ulysses spacecraft.
These results are employed as inputs for modelled slab
and 2D turbulence energy spectra. The latter spectrum is
chosen based on physical considerations, with a drop-off
at the very lowest wavenumbers commencing at the 2D
outerscale. There currently exist no models or observations
for this quantity, and it is the only free parameter
in this study. The modelled turbulence spectra are used
as inputs for parallel mean free path expressions based
on those derived from quasi-linear theory and perpendicular
mean free paths from extended nonlinear guiding
center theory. Furthermore, the effects of turbulence on
cosmic-ray drifts are modelled in a self-consistent way,
employing a recently developed model for drift along
the wavy current sheet. The resulting diffusion coefficients
and drift expressions are applied to the study of
galactic cosmic-ray protons and antiprotons using a threedimensional,
steady-state cosmic-ray modulation code, and
sample solutions in fair agreement with multiple spacecraft
observations are presented.