Abstract
Contrary to tropospheric CO2 whose oxygen isotopic composition follows a standard
mass dependent relationship, i.e. 17O 0.5 18O, stratospheric CO2 is preferentially
enriched in 17O, leading to a strikingly different relation with 17O 1.7 18O. The isotope
anomaly is likely inherited from O3 via photolytically produced O(1 5 D) that undergoes
isotope exchange with CO2 and the anomaly may well serve as a tracer of stratospheric
chemistry if details of the exchange mechanism are understood. We have
studied the photochemical isotope equilibrium in UV-irradiated O2-CO2 and O3-CO2
mixtures to quantify the transfer of the anomaly from O3 to CO2 at room temperature.
10 By following the time evolution of the oxygen isotopic compositions of CO2 and O2 under
varying initial isotopic compositions of both, O2/O3 and CO2, the isotope equilibria
between the two reservoirs were determined. A very strong dependence of the isotope
equilibrium on the O2/CO2-ratio was established. Equilibrium enrichments of 17O and
18O in CO2 relative to O2 diminish with increasing CO2 content, and this reduction in the
15 equilibrium enrichments does not follow a standard mass dependent relation. When
molecular oxygen exceeds the amount of CO2 by a factor of about 20, 17O and 18O
in equilibrated CO2 are enriched by (142±4)‰ and (146±4)‰, respectively, at room
temperature and at a pressure of 225 hPa, independent of the initial isotopic compositions
of CO2 and O2 or O3. From these findings we derive a simple and general
20 relation between the starting isotopic compositions and amounts of O2 and CO2 and
the observed slope in a three oxygen isotope diagram. Predictions from this relation
are compared with published laboratory and atmospheric data.
Original language | Undefined/Unknown |
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Pages (from-to) | 7869-7904 |
Number of pages | 36 |
Journal | Atmospheric Chemistry and Physics Discussions |
Volume | 6 |
Publication status | Published - 2006 |