Atmospheric Chemistry and Physics
www.atmos-chem-phys.net
1680-7316
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3
1
2003
10.5194/acp-3-107-2003
http://www.atmos-chem-phys.net/3/107/2003/
http://www.atmos-chem-phys.net/3/107/2003/acp-3-107-2003.html
http://www.atmos-chem-phys.net/3/107/2003/acp-3-107-2003.pdf
107
118
2003-02-07
A discussion on the determination of atmospheric OH and its trends
P. Jöckel
C. A. M. Brenninkmeijer
P. J. Crutzen
Max Planck Institute for Chemistry, POB 3060, 55020 Mainz, Germany
Scripps Institution of Oceanographicy, University of California, San Diego, USA
The oxidation efficiency of the troposphere is largely determined by the
hydroxyl radical and its global distribution. Its presence limits the lifetime of most trace gases.
Because of the great importance of several of these gases for climate, ozone budget and
OH itself, it is of fundamental importance to acquire knowledge about atmospheric
OH and possible trends in its concentrations. In the past, average concentrations of
OH and trends were largely derived using industrially produced CH<sub>3</sub>CCl<sub>3</sub> as a chemical
tracer. The analyses have given valuable, but also rather uncertain results. In this paper we
describe an idealized computer aided tracer experiment which has as one of
its goals to derive tracer concentration weighted, global average <<i>k</i>(OH)>, where
the temporal and spatial OH distribution is prescribed and <i>k</i> is the
reaction rate coefficient of OH with a hitherto never produced (Gedanken) tracer, which is injected at a number of surface sites in the atmosphere in
well known amounts over a given time period. Using a three-dimensional (3-D)
time-dependent chemistry transport model, <<i>k</i>(OH)> can be accurately determined
from the calculated 3-D tracer distribution. It is next explored how well
<<i>k</i>(OH)> can be retrieved solely from tracer measurements at a limited number of
surface sites. The results from this analysis are encouraging enough to actually think about the feasibility to carry out a global dedicated tracer
experiment to derive <<i>k</i>(OH)> and its temporal trends. However, before that, we
propose to test the methods that are used to derive <<i>k</i>(OH)>, so far largely
using CH<sub>3</sub>CCl<sub>3</sub>, with an idealized tracer experiment, in which a
global chemistry transport model is used to calculate the ``Gedanken'' tracer distribution,
representing the real 3-D world, from which <<i>k</i>(OH)> is derived, using only
the tracer information from a limited set of surface sites. We propose here
that research groups which are, or will be, involved in global average OH studies to participate in such an inter-comparison of methods, organized and
over-seen by a committee appointed by the International Global Atmospheric
Chemistry (IGAC) program.