Reducing methane (CH₄) emissions is now a top priority for climate action because of its short lifetime and high global warming potential. Emissions from fossil fuel exploitation sectors (oil-gas extraction, coal mining, geological), accounting for 33% of global anthropogenic CH₄ emissions, are the most attractive and cost-effective mitigation option. However, the estimated CH₄emissions and trends of the fossil-fuel sector are largely uncertain across the existing inventories (e.g., EDGAR, GAINSv4, FAO estimates, etc.) and source/sink inversions of atmospheric CH₄. The atmospheric CH₄ data alone do not provide source-type information and hence cannot constrain magnitudes of specific sectors. Stable carbon isotope ratio of CH₄ (δ¹³C-CH₄) in the atmosphere is controlled by relative contributions from different source types with distinctive isotope signatures, and could help to probe sectoral emissions with the help of the atmospheric chemistry-transport model (ACTM).

We have simulated the global history (1985-2020) of CH₄ and δ¹³C-CH₄ using MIROC4-ACTM and compared with the measurement results at networks of monitoring stations (e.g., INSTAAR, TU/NIPR, MPI, etc.). The base simulations (based on anthropogenic CH₄ emissions from the EDGARv6 database) could not reproduce the observed atmospheric CH₄ and δ¹³C-CH₄(Fig. 1). The discrepancy between the observed and modelled CH₄ and δ¹³C-CH₄ suggest incomplete knowledge of emissions used for baseline simulations. Different sensitivity experiments are performed by revising fugitive fossil fuel emissions (from different inventories and literature) and spatially resolved distributions of δ¹³C-CH₄ source signatures to reproduce the measurements. The emission scenario (sONG-Coal_geol19) is then prepared by using GAINSv4 inventory for Oil and Gas, coal mining and scaled natural geological sectors, which reproduces the trend and meridional gradients in the observed CH₄ and δ¹³C-CH₄ (Fig. 1), but does not compare well with the absolute δ¹³C-CH₄ values. Spatially resolved δ¹³C-CH₄ source signatures in place of globally invariant source signature helps to reduce the mismatch between observed and simulated δ¹³C-CH₄ from ~1 ‰ to less than 0.1 ‰ (magenta line lower panel of Fig. 1). The most likely emission scenario, which can reconstruct the latitudinal gradient and trends in atmospheric CH₄ and δ¹³C-CH₄ simultaneously suggests a decreasing-to-constant emissions from fossil fuel exploitations 1985-2020, contrary to an increasing trend in EDGARv6 inventory. This study suggests that the increase in atmospheric CH₄ after 2006 is primarily due to microbial sources, mainly the agricultural and waste management sector. The detail will be presented in the meeting.

Figure 1. Comparison of modelled CH₄ and δ¹³C-CH₄ with observations (black circle) made by Tohoku University (TU) and National Institute of Polar Research (NIPR) at two northern and southern surface baseline stations, Ny-Alesund, Svalbard and Syowa, Antarctica.