Abstract
In the global methane budget, the largest natural source is attributed to wetlands that encompass all ecosystems composed of waterlogged or inundated ground, capable of methane production. Among them, northern peatlands that store large amounts of soil organic carbon have been functioning, since the end of the last glaciation period, as long-term sources of methane (CH4) and are one of the most significant methane sources among wetlands. To reduce global methane budget uncertainties, it is of significance to understand processes driving methane production and fluxes in northern peatlands. A methane model that features methane production and transport by plants, ebullition process and diffusion in soil, oxidation to CO2 and CH4 fluxes to the atmosphere has been embedded in the ORCHIDEE-PEAT land surface model which includes an explicit representation of northern peatlands. This model, ORCHIDEE-PCH4 was calibrated and evaluated on 14 peatland sites distributed on both Eurasian and American continents in the northern boreal and temperate regions. Data assimilation approaches were employed to optimized parameters at each site and at all sites simultaneously. Results show that, in ORCHIDEE-PCH4, methanogenesis is sensitive to temperature and substrate availability over the top 75 cm of soil depth. Methane emissions estimated using single site optimization (SSO) of model parameters are underestimated by 9 g CH4 m−2 year−1 on average (i.e. 50 % higher than the site average of yearly methane emissions). While using the multi-sites optimization (MSO), methane emissions are overestimated by 5 g CH4 m−2 year−1 on average across all investigated sites (i.e. 37 % lower than the site average of yearly methane emissions).
Highlights
Atmospheric methane level estimated from ice cores analysis (Etheridge et al, 1998) and in situ measurements (Blake et al, 1982; Dlugokencky, 2019; Prinn et al, 2018) have nearly tripled since the pre-industrial equilibrium value i.e., 65 from 680 ppb to reach a value of 1892 ppb in December 2020 ( Dlugokencky, 2021; Saunois et al, 2020)
700 peatlands and permafrost features embedded in the most recent version of ORCHIDEE-PEAT v2.0. This modified version, ORCHIDEE-PCH4 which was used in this study, integrates a vertical discretization of oxic and anoxic decomposition of soil organic carbon of northern peatlands and subsequent methane production, oxidation and transport by vascular plants, ebullition and diffusion in soil and snow layers
A sensitivity analysis of methane emissions was performed on changes of 7 model parameters optimized with site-level measurements of 14 sites located northern than 41°N on the Eurasian and
Summary
Atmospheric methane level estimated from ice cores analysis (Etheridge et al, 1998) and in situ measurements (Blake et al, 1982; Dlugokencky, 2019; Prinn et al, 2018) have nearly tripled since the pre-industrial equilibrium value i.e., 65 from 680 ppb to reach a value of 1892 ppb in December 2020 ( Dlugokencky, 2021; Saunois et al, 2020) This increase is consistent with the world population increase and the industrialization, for instance the increase of fossil fuel extraction and use, of organic waste generation, and of livestock numbers (Raynaud et al, 2003). 80 peatlands are large soil organic carbon reservoirs that could be functioning as a source of CH4 and source or a sink of CO2 to the atmosphere They cover around 3% of surface continental lands but store around one third of the global soil carbon (Gorham, 1991).
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