Astronomy and Astrophysics – Astronomy
Scientific paper
May 1998
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1998apj...499..234c&link_type=abstract
Astrophysical Journal v.499, p.234
Astronomy and Astrophysics
Astronomy
133
Molecular Processes, Ism: Clouds, Ism: Cosmic Rays, Diffusion, Ism: Abundances
Scientific paper
The degree of ionization, x(e) = n(e)/n(H2), and the cosmic-ray ionization rate, zeta , in 24 cloud cores have been determined by comparing observational data from Butner et al. on the abundance ratios RD = [DCO+]/[HCO+] and RH = [HCO+]/[CO] with a simple analytical chemical model and with a detailed "pseudo-time-dependent" chemical model. The results are dependent on the depletion of elemental carbon and oxygen from their cosmic abundances, especially for cores with a low degree of ionization. We determine the depletion of C and O from the measured HC3N/CO abundance ratios using model results. We find that the range of fractional ionization in the dark cores extends from ~10-6 to ~10-8, with inferred cosmic ray ionization rates in the range of 10-16-10-18 s-1. This corresponds to ambipolar diffusion timescales of between 3 x 107 and 3 x 105 yr, with a median value of 5 x 106 yr. The ratio of ambipolar diffusion to the free-fall timescales varies between 3 and 200, with a median value of 50. We find, rather surprisingly, no clear segregation in the ambipolar diffusion timescales between cores with embedded stars and those without. An interesting by-product of our results is the conclusion that the cyanopolyyne-rich core in TMC-1 is atypical in its abundance distribution and may be unusually young.
Caselli Paola
Herbst Eric
Terzieva Radoslava
Walmsley Charles Malcolm
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