Sota Arakawa, Daiki Yamamoto, Lily Ishizaki, Tamami Okamoto, Noriyuki Kawasaki
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Oxygen Isotope Exchange Between Dust Aggregates and Ambient Nebular Gas
Meteorites and their components exhibit a diverse range of oxygen isotope
compositions, and the isotopic exchange timescale between dust grains and
ambient gas is a key parameter for understanding the spatiotemporal evolution
of the solar nebula. As dust grains existed as macroscopic aggregates in the
solar nebula, it is necessary to consider the isotopic exchange timescales for
these aggregates. Here, we theoretically estimate the isotope exchange
timescales between dust aggregates and ambient vapor. The isotope exchange
process between aggregates and ambient vapor is divided into four processes:
(i) supply of gas molecules to the aggregate surface, (ii) diffusion of
molecules within the aggregate, (iii) isotope exchange on the surface of
constituent particles, and (iv) isotope diffusion within the particles. We
evaluate these timescales and assess which one becomes the rate-determining
step. We reveal that the isotope exchange timescale is approximately the same
as that of the constituent particles when the aggregate radius is smaller than
the critical value, which is a few centimeters when considering the exchange
reaction between amorphous forsterite aggregates and water vapor.
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