Strong Sensitivity of the Isotopic Composition of Methane to the Plausible Range of Tropospheric Chlorine

Strong Sensitivity of the Isotopic Composition of Methane to the Plausible Range of Tropospheric Chlorine

The C-13 isotopic ratio of methane, δC-13 of CH4, provides additional constraints on the CH4 budget to complement the constraints from CH4 observations. The interpretation of δC-13 observations is complicated, however, by uncertainties in the methane sink. The reaction of CH4 with Cl is highly fract...

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Veröffentlicht in:Atmospheric chemistry and physics 2020-07, Vol.20 (14), p.8405-8419
Hauptverfasser: Strode, Sarah A, Wang, James S, Manyin, Michael, Duncan, Bryan, Hossaini, Ryan, Keller, Christoph A, Michel, Sylvia E., White, James W. C.
Format: Artikel
Sprache:eng
Schlagworte:
Analysis
Biomass
Chemical composition
Chemical transport
Chlorine
Composition
Computer simulation
Environmental Sciences
Environmental Sciences & Ecology
Fields
Fractionation
Geographical distribution
Geophysics
Halogens
Isotope composition
Isotopes
Life Sciences & Biomedicine
Meteorology & Atmospheric Sciences
Methane
Physical Sciences
Relative abundance
Science & Technology
Seasonal distribution
Seasonal variation
Sensitivity
Sensitivity analysis
Simulation
Troposphere
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Zusammenfassung:The C-13 isotopic ratio of methane, δC-13 of CH4, provides additional constraints on the CH4 budget to complement the constraints from CH4 observations. The interpretation of δC-13 observations is complicated, however, by uncertainties in the methane sink. The reaction of CH4 with Cl is highly fractionating, increasing the relative abundance of 13CH4, but there is currently no consensus on the strength of the tropospheric Cl sink. Global model simulations of halogen chemistry differ strongly from one another in terms of both the magnitude of tropospheric Cl and its geographic distribution. This study explores the impact of the inter-model diversity in Cl fields on the simulated δC-13 of CH4. We use a set of GEOS global model simulations with different predicted Cl fields to test the sensitivity of the δC-13 of CH4 to the diversity of Cl output from chemical transport models. We find that δC-13 is highly sensitive to both the amount and geographic distribution of Cl. Simulations with Cl providing 0.28% or 0.66% of the total CH4 loss bracket the δC-13 observations for a fixed set of emissions. Thus, even when Cl provides only a small fraction of the total CH4 loss and has a small impact on total CH4, it provides a strong lever on δC-13. Consequently, it is possible to achieve a good representation of total CH4 using widely different Cl concentrations, but the partitioning of CH4 loss between the OH and Cl reactions leads to strong differences in isotopic composition depending on which model’s Cl field is used. Comparing multiple simulations, we find that altering the tropospheric Cl field leads to approximately a 0.5‰ increase in δ(13)CH4for each percent increase in how much CH4 is oxidized by Cl. The geographic distribution and seasonal cycle of Cl also impacts the hemispheric gradient and seasonal cycle of δC-13. The large effect of Cl on δC-13 compared to total CH4 broadens the range of CH4 source mixtures that can be reconciled with δC-13 observations. Stronger constraints on tropospheric Cl are necessary to improve estimates of CH4 sources from δC-13 observations.
ISSN:1680-7316
1680-7324
1680-7324
DOI:10.5194/acp-20-8405-2020