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| Titel |
Assessing nucleation in cloud formation modelling for Brown Dwarf and Exoplanet atmospheres |
| VerfasserIn |
Graham Lee, Christiane Helling, Helen Giles, Stefan Bromley |
| Konferenz |
EGU General Assembly 2015
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| Medientyp |
Artikel
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| Sprache |
Englisch
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| Digitales Dokument |
PDF |
| Erschienen |
In: GRA - Volume 17 (2015) |
| Datensatznummer |
250110736
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| Publikation (Nr.) |
 EGU/EGU2015-10763.pdf |
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| Zusammenfassung |
| Context. Substellar objects such as Brown Dwarfs and hot Jupiter exoplanets are cool
enough that clouds can form in their atmospheres (Helling & Casewell 2014; A&ARv 22)).
Unlike Earth, where cloud condensation nuclei are provided by the upward motion of sand or
ash, in Brown Dwarf and hot Jupiters these condensation seeds form from the gas phase.
This process proceeds in a stepwise chemical reaction of single monomer addition
of a single nucleation species, referred to as homogeneous nucleation. The rate
at which these seeds form is determined by the local thermodynamic conditions
and the chemical composition of the local gas phase. Once the seed particles have
formed, multiple materials are thermally stable and grow almost simultaneously by
chemical surface reactions. This results in the growth of the condensation seeds to
macroscopic particles of μm size. At the same time, the gas phase becomes depleted.
Once temperatures become too high for thermal stability of the cloud particle, it
evaporates until its constituents return to the gas phase. Convection from deeper
atmospheric layers provides element replenishment to upper, cooler layers allowing the
cloud formation process to reach a stationary state (Woitke & Helling 2003; A&A
399).
Aims. The most efficient nucleation is a ‘winner takes all’ process as the losing molecules
will condense on the surface of the faster nucleating seed particle. We apply new molecular
(TiO2)N-cluster and SiO vapour data to our cloud formation model in order to re-asses the
question of the primary nucleation species.
Methods. We apply density functional theory (B3LYP, 6-311G(d)) using the computational
chemistry package GAUSSIAN 09 to derive updated thermodynamical data for
(TiO2)N-clusters as input for our TiO2 seed formation model. We test both TiO2 and SiO as
primary nucleates assuming a homogeneous nucleation process and by solving
a system of dust moment equations and element conservation for a pre-scribed
Brown Dwarf/hot Jupiter DRIFT-PHOENIX atmospheric model temperature-pressure
structure.
Results. We present updated Gibbs free energies for the new (TiO2)N-clusters. We discuss
the effect of this new data on the resulting cloud structure and cloud properties like particle
number density, grain sizes and grain composition. We find SiO to be the more efficient
nucleation species. However, subsequent SiO condensation onto seed particle mantles result
in element depletion, reducing the number density of gaseous SiO and reducing the efficiency
of nucleation. Therefore, TiO2 remains therefore the primary nucleation species (Lee et al.
2014; arXiv:1410.6610). |
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