Document 
-
Articles citing this article
- Same authors
-
Related articles
- Recommend this article
- Download citation
- Alert me when this article is cited
- Alert me when this article is corrected
BibSonomy
CiteUlike
Connotea
Del.icio.us
Digg
Facebook
|
A&A 400, 585-593 (2003)
DOI: 10.1051/0004-6361:20021902
Moment equations for chemical reactions on interstellar dust grains
A. Lipshtat and O. BihamRacah Institute of Physics, The Hebrew University, Jerusalem 91904, Israel
(Received 21 November 2002 / Accepted 16 December 2002 )
Abstract
While most chemical reactions in the interstellar medium take place in the gas phase,
those occurring on the surfaces of dust grains play an essential role.
Such surface reactions include the catalytic production of molecular hydrogen
as well as more complex reaction networks producing
ice mantles and various organic molecules.
Chemical models based on rate equations
including both gas phase and grain surface reactions have been used
in order
to simulate the formation of chemical complexity in interstellar clouds.
For reactions in the gas phase
and on large grains,
rate equations,
which are highly efficient to simulate,
are an ideal tool.
However, for
small grains
under low flux,
the typical
number of atoms or molecules of certain reactive species
on a grain may go down to order one or less.
In this case
the discrete nature of the populations of reactive species as well as
the fluctuations become dominant, thus
the mean-field approximation
on which the rate equations are based does not apply.
Recently, a master equation approach that provides a good
description of chemical reactions on interstellar dust grains
was proposed.
Here we present a related approach based on moment equations
that can be obtained from the master equation.
These equations describe the time evolution
of the moments of the distribution of the population
of the various chemical species
on the grain.
An advantage of this approach is the fact that
the production rates of molecular species are expressed directly in terms of
these moments.
Here we use the moment equations to calculate the rate of
molecular hydrogen formation on small grains.
It is shown that the moment equation approach is efficient
in this case in which only a single reactive species is involved.
The set of equations for the case of two species is presented
and the difficulties in implementing this approach for complex
reaction networks involving multiple species are discussed.
Key words: ISM: molecules -- molecular processes
Offprint request: O. Biham, biham@phys.huji.ac.il
© ESO 2003
| What is OpenURL? |
