Interstellar Metastable Helium Absorption as a Probe of the Cosmic-Ray Ionization Rate

TL;DR

This study explores using the 10830 A absorption line of metastable helium to estimate the cosmic-ray ionization rate in interstellar clouds, providing a new method with an upper limit close to previous estimates.

Contribution

It introduces a novel approach to measure cosmic-ray ionization rates via metastable helium absorption, accounting for complex chemistry and excitation mechanisms.

Findings

Derived an upper limit for helium ionization rate: < 1.2 x 10^-15 s^-1

Found the new upper limit is about five times higher than previous H3+ based estimates

Demonstrated the feasibility and challenges of observing interstellar metastable helium

Abstract

The ionization rate of interstellar material by cosmic rays has been a major source of controversy, with different estimates varying by three orders of magnitude. Observational constraints of this rate have all depended on analyzing the chemistry of various molecules that are produced following cosmic-ray ionization, and in many cases these analyses contain significant uncertainties. Even in the simplest case (H3+) the derived ionization rate depends on an (uncertain) estimate of the absorption path length. In this paper we examine the feasibility of inferring the cosmic-ray ionization rate using the 10830 A absorption line of metastable helium. Observations through the diffuse clouds toward HD 183143 are presented, but yield only an upper limit on the metastable helium column density. A thorough investigation of He+ chemistry reveals that only a small fraction of He+ will recombine into the triplet state and populate the metastable level. In addition, excitation to the triplet manifold of helium by secondary electrons must be accounted for as it is the dominant mechanism which produces He* in some environments. Incorporating these various formation and destruction pathways, we derive new equations for the steady state abundance of metastable helium. Using these equations in concert with our observations, we find zeta_He < 1.2*10^-15 s^-1, an upper limit about 5 times larger than the ionization rate previously inferred for this sight line using H3+. While observations of interstellar He* are extremely difficult at present...