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CO Diffusion and Desorption Kinetics in CO 2 Ices

Cooke, Ilsa R. ; Öberg, Karin I. ; Fayolle, Edith C. ; Peeler, Zoe ; Bergner, Jennifer B.

The Astrophysical journal, 2018-01, Vol.852 (2), p.75 [Periódico revisado por pares]

American Astronomical Society

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  • Título:
    CO Diffusion and Desorption Kinetics in CO 2 Ices
  • Autor: Cooke, Ilsa R. ; Öberg, Karin I. ; Fayolle, Edith C. ; Peeler, Zoe ; Bergner, Jennifer B.
  • Assuntos: Physics
  • É parte de: The Astrophysical journal, 2018-01, Vol.852 (2), p.75
  • Descrição: Abstract The diffusion of species in icy dust grain mantles is a fundamental process that shapes the chemistry of interstellar regions; yet, measurements of diffusion in interstellar ice analogs are scarce. Here we present measurements of CO diffusion into CO 2 ice at low temperatures ( T  = 11–23 K) using CO 2 longitudinal optical phonon modes to monitor the level of mixing of initially layered ices. We model the diffusion kinetics using Fick’s second law and find that the temperature-dependent diffusion coefficients are well fit by an Arrhenius equation, giving a diffusion barrier of 300 ± 40 K. The low barrier along with the diffusion kinetics through isotopically labeled layers suggest that CO diffuses through CO 2 along pore surfaces rather than through bulk diffusion. In complementary experiments, we measure the desorption energy of CO from CO 2 ices deposited at 11–50 K by temperature programmed desorption and find that the desorption barrier ranges from 1240 ± 90 K to 1410 ± 70 K depending on the CO 2 deposition temperature and resultant ice porosity. The measured CO–CO 2 desorption barriers demonstrate that CO binds equally well to CO 2 and H 2 O ices when both are compact. The CO–CO 2 diffusion–desorption barrier ratio ranges from 0.21 to 0.24 dependent on the binding environment during diffusion. The diffusion–desorption ratio is consistent with the above hypothesis that the observed diffusion is a surface process and adds to previous experimental evidence on diffusion in water ice that suggests surface diffusion is important to the mobility of molecules within interstellar ices.
  • Editor: American Astronomical Society
  • Idioma: Inglês
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  • Realização: ABCD-USP USP   Logos de Redes Sociais: Freepik

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