p, He, and C to Fe cosmic-ray primary fluxes in diffusion models: Source and transport signatures on fluxes and ratios

Abstract

The propagated fluxes of proton, helium, and heavier primary cosmic-ray species (up to Fe) are a means to indirectly access the source spectrum of cosmic rays. We check the compatibility of the primary fluxes with the transport parameters derived from the B/C analysis, but also if they bring further constraints. Proton data are well described in the simplest model defined by a power-law source spectrum and plain diffusion. They can also be accommodated by models with, e.g., convection and/or reacceleration. There is no need for breaks in the source spectral indices below 1 TeV/n. Fits on the primary fluxes alone do not provide physical constraints on the transport parameters. If we let free the source spectrum dQ/dE = q βηS R-α and fix the diffusion coefficient K(R)= K0βηT Rδ such as to reproduce the B/C ratio, the MCMC analysis constrains the source spectral index α to be in the range 2.2-2.5 for all primary species up to Fe, regardless of the value of the diffusion slope δ. The ηS low-energy shape of the source spectrum is degenerate with the low-energy shape ηT of the diffusion coefficient: we find ηS-ηT≈ 0 for p and He data, but ηS-ηT≈ 1 for C to Fe primary species. This is consistent with the toy-model calculation in which the shape of the p/He and C/O to Fe/O data is reproduced if ηS-ηT≈ 0-1 (no need for different slopes α). When plotted as a function of the kinetic energy per nucleon, the low-energy p/He ratio is shaped mostly by the modulation effect, whereas primary/O ratios are mostly shaped by their destruction rate.