Cosmic-ray propagation in the Galaxy and in the heliosphere - The path-length distribution at low energy

Citations Over TimeTop 10% of 1987 papers

Abstract

The energy dependence of the path-length distribution of cosmic rays at low energies, below relativistic velocities, is studied, and its implications for models of cosmic-ray confinement and propagation in the Galaxy and Galactic halo, including the effects of a possible Galactic wind, are studied. It is found that the mean free path in Galactic propagation must be fully energy-dependent, with the mean of an exponential path-length distribution increasing with increasing energy below 1 GeV per nucleon and decreasing with increasing energy above 1 GeV per nucleon. This indicates that, at low energies, diffusion is not the controlling process. The path-length distribution is not purely exponential but is depleted in short path lengths at low energies. This depletion is energy-dependent, being largest at low energies and decreasing with increasing energy.

Related Papers

• → Where is the cosmic-ray modulation boundary of the heliosphere?(2015)35 cited
• → Cosmic ray transport near the heliopause(2015)4 cited
• → Modeling of the TeV cosmic-ray anisotropy based on intensity mapping in an MHD-simulated heliosphere(2021)