Complete Depletion in prestellar cores

We have carried out calculations of ionization equilibrium and deuterium fractionation for conditions appropriate to a completely depleted, low mass pre--protostellar core, where heavy elements such as C, N, and O have vanished from the gas phase and are incorporated in ice mantles frozen on dust gr...

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Bibliographic Details
Published inarXiv.org
Main Authors Walmsley, C M, Flower, D R, G Pineau des Forets
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 20.02.2004
Subjects
Ambipolar diffusion
Depletion
Deuterium
Fractionation
Grain size distribution
Heavy elements
Ionization
Kinematics
Particle size distribution
Protostars
Vapor phases
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Summary:We have carried out calculations of ionization equilibrium and deuterium fractionation for conditions appropriate to a completely depleted, low mass pre--protostellar core, where heavy elements such as C, N, and O have vanished from the gas phase and are incorporated in ice mantles frozen on dust grain surfaces. We put particular emphasis on the interpretation of recent observations of H2D+ towards the centre of the prestellar core L1544 (Caselli et al. 2003) and also compute the ambipolar diffusion timescale. We consider explicitly the ortho and para forms of H2,H3+, and H2D+. Our results show that the ionization degree under such conditions depends sensitively on the grain size distribution or, more precisely, on the mean grain surface area per hydrogen nucleus. Depending upon this parameter and upon density, the major ion may be H+, H3+, or D3+. We show that the abundance of ortho-H2D+ observed towards L1544 can be explained satisfactorily in terms of a complete depletion model and that this species is, as a consequence, an important tracer of the kinematics of prestellar cores.
ISSN:2331-8422
DOI:10.48550/arxiv.0402493