Energy losses of solar cosmic rays in interplanetary space

Abstract

A simple model of solar cosmic ray propagation which includes diffusion, convection, and energy loss by adiabatic deceleration is studied. A Monte Carlo technique is employed to investigate the variation of mean particle energy in the interplanetary medium after the impulsive release of mono-energetic particles at the Sun. At 1 AU typical energy losses are 43% at 20 h and 64% at 60 h after particle release for a diffusion coefficient κ(r)=κ 0rβ with β=+1/2 and κ0=1.33 × 1021 cm2 s−1. When κ 0 in this model is reduced by a factor of 4, the energy loss is greater by a factor of 2 at 60 h after particle release. When β is increased, the energy losses are greater. Using the model parameters above, an increase in solar wind speed from 300 to 600 km s−-1 gives rise to energy losses that are greater again by factor of 2 at a time of 60 h. Results are compared with an observation by Murray et al. (1971) of a ‘knee’ in the energy spectrum of solar protons. It is not considered likely that the change in the energy of the knee with time requires, in addition to adiabatic deceleration, another energy change process which acts to increase the energy of particles.