Model Analysis of the Factors Regulating Trends and Variability of Methane, Carbon Monoxide and OH

Abstract:

Methane (CH₄) is the second most important anthropogenic greenhouse gas (GHG). Its 100-year global warming potential (GWP) is 25 times larger than that for carbon dioxide. Oxidation of CH₄ by OH is the main loss process, thus affecting the oxidizing capacity of the atmosphere and contributing to the global ozone background. The 100-yr integrated GWP of CH₄ is sensitive to changes in OH levels and feedbacks of CH₄ emission itself. In this study we implement a computationally efficient CH₄-CO-OH parameterization into the NASA GEOS5-AGCM to simulate CO, OH and CH₄ over the last three decades. We use this efficient interactive parameterization to investigate the CH₄, CO and OH trends and variability and will compare the results to a CH₄-only (with fixed CO and OH fields) as well as to a full chemistry model setup, constrained with CH₄ fluxes, to see how differences in simulated OH may impact methane. We will investigate the key chemical processes that may affect the global OH budgets and thus the CH₄ lifetime and trends. In this context, we will investigate the global OH-recycling as well as the impact of important OH sources. The results will be validated with a suite of ground based and satellite measurements. The results are expected to improve our understanding of OH and CH₄ global budget and trends.