Abstract

Reducing methane (CH₄) emissions is an attractive option for jointly addressing climate and ozone (O₃) air quality goals. With multi-decadal full-chemistry transient simulations in the MOZART-2 tropospheric chemistry model, we show that tropospheric O₃ responds approximately linearly to changes in CH₄ emissions over a range of anthropogenic emissions from 0-430 Tg CH₄ yr^-1 (0.11-0.16 Tg tropospheric O₃ or ~11-15 pptv surface O₃ decrease per Tg yr^-1 CH₄ reduced). We find that neither the air quality nor climate benefits depend strongly on the location of the CH₄ emission reductions, implying that the lowest cost emission controls can be targeted. With a series of future (2005-2030) transient simulations, we demonstrate that cost-effective CH₄ controls would offset the positive climate forcing from CH₄ and O₃ that would otherwise occur (from increases in NO_x and CH₄ emissions in the baseline scenario) and improve O₃ air quality. We estimate that anthropogenic CH₄ contributes 0.7 Wm^-2 to climate forcing and ~4 ppbv to surface O₃ in 2030 under the baseline scenario. Although the response of surface O₃ to CH₄ is relatively uniform spatially compared to that from other O₃ precursors, it is strongest in regions where surface air mixes frequently with the free troposphere and where the local O₃ formation regime is NO_x-saturated. In the model, CH₄ oxidation within the boundary layer (below ~2.5 km) contributes more to surface O₃ than CH₄ oxidation in the free troposphere. In NO_x-saturated regions, the surface O₃ sensitivity to CH₄ can be twice that of the global mean, with >70% of this sensitivity resulting from boundary layer oxidation of CH₄. Accurately representing the NO_x distribution is thus crucial for quantifying the O₃ sensitivity to CH₄.