TY - JOUR
T1 - The isotopic composition of methane in the stratosphere: high-altitude balloon sample measurements
AU - Röckmann, T.
AU - Brass, M.
AU - Borchers, R.
AU - Engel, A.
PY - 2011
Y1 - 2011
N2 - The isotopic composition of stratospheric
methane has been determined on a large suite of air samples
from stratospheric balloon flights covering subtropical
to polar latitudes and a time period of 16 yr. 154 samples
were analyzed for 13C and 119 samples for D, increasing
the previously published dataset for balloon borne samples
by an order of magnitude, and more than doubling the total
available stratospheric data (including aircraft samples)
published to date. The samples also cover a large range in
mixing ratio from tropospheric values near 1800 ppb down
to only 250 ppb, and the strong isotope fractionation processes
accordingly increase the isotopic composition up to
13C= −14‰ and D= +190 ‰, the largest enrichments
observed for atmospheric CH4 so far. When analyzing and
comparing kinetic isotope effects (KIEs) derived from single
balloon profiles, it is necessary to take into account the
residence time in the stratosphere in combination with the
observed mixing ratio and isotope trends in the troposphere,
and the range of isotope values covered by the individual profile.
The isotopic composition of CH4 in the stratosphere is
affected by both chemical and dynamical processes. This
severely hampers interpretation of the data in terms of the
relative fractions of the three important sink mechanisms (reaction
with OH, O(1D) and Cl). It is shown that a formal sink
partitioning using the measured data severely underestimates
the fraction removed by OH, which is likely due to the insensitivity
of the measurements to the kinetic fractionation in
the lower stratosphere. Full quantitative interpretation of the
CH4 isotope data in terms of the three sink reactions requires
a global model.
AB - The isotopic composition of stratospheric
methane has been determined on a large suite of air samples
from stratospheric balloon flights covering subtropical
to polar latitudes and a time period of 16 yr. 154 samples
were analyzed for 13C and 119 samples for D, increasing
the previously published dataset for balloon borne samples
by an order of magnitude, and more than doubling the total
available stratospheric data (including aircraft samples)
published to date. The samples also cover a large range in
mixing ratio from tropospheric values near 1800 ppb down
to only 250 ppb, and the strong isotope fractionation processes
accordingly increase the isotopic composition up to
13C= −14‰ and D= +190 ‰, the largest enrichments
observed for atmospheric CH4 so far. When analyzing and
comparing kinetic isotope effects (KIEs) derived from single
balloon profiles, it is necessary to take into account the
residence time in the stratosphere in combination with the
observed mixing ratio and isotope trends in the troposphere,
and the range of isotope values covered by the individual profile.
The isotopic composition of CH4 in the stratosphere is
affected by both chemical and dynamical processes. This
severely hampers interpretation of the data in terms of the
relative fractions of the three important sink mechanisms (reaction
with OH, O(1D) and Cl). It is shown that a formal sink
partitioning using the measured data severely underestimates
the fraction removed by OH, which is likely due to the insensitivity
of the measurements to the kinetic fractionation in
the lower stratosphere. Full quantitative interpretation of the
CH4 isotope data in terms of the three sink reactions requires
a global model.
U2 - 10.5194/acp-11-13287
DO - 10.5194/acp-11-13287
M3 - Article
SN - 1680-7316
VL - 11
SP - 13287
EP - 13304
JO - Atmospheric chemistry and physics
JF - Atmospheric chemistry and physics
ER -