Abstract
Abstract. Natural methane (CH4) emissions from wet ecosystems are an important part of today's global CH4 budget. Climate affects the exchange of CH4 between ecosystems and the atmosphere by influencing CH4 production, oxidation, and transport in the soil. The net CH4 exchange depends on ecosystem hydrology, soil and vegetation characteristics. Here, the LPJ-WHyMe global dynamical vegetation model is used to simulate global net CH4 emissions for different ecosystems: northern peatlands (45°–90° N), naturally inundated wetlands (60° S–45° N), rice agriculture and wet mineral soils. Mineral soils are a potential CH4 sink, but can also be a source with the direction of the net exchange depending on soil moisture content. The geographical and seasonal distributions are evaluated against multi-dimensional atmospheric inversions for 2003–2005, using two independent four-dimensional variational assimilation systems. The atmospheric inversions are constrained by the atmospheric CH4 observations of the SCIAMACHY satellite instrument and global surface networks. Compared to LPJ-WHyMe the inversions result in a~significant reduction in the emissions from northern peatlands and suggest that LPJ-WHyMe maximum annual emissions peak about one month late. The inversions do not put strong constraints on the division of sources between inundated wetlands and wet mineral soils in the tropics. Based on the inversion results we diagnose model parameters in LPJ-WHyMe and simulate the surface exchange of CH4 over the period 1990–2008. Over the whole period we infer an increase of global ecosystem CH4 emissions of +1.11 Tg CH4 yr−1, not considering potential additional changes in wetland extent. The increase in simulated CH4 emissions is attributed to enhanced soil respiration resulting from the observed rise in land temperature and in atmospheric carbon dioxide that were used as input. The long-term decline of the atmospheric CH4 growth rate from 1990 to 2006 cannot be fully explained with the simulated ecosystem emissions. However, these emissions show an increasing trend of +3.62 Tg CH4 yr−1 over 2005–2008 which can partly explain the renewed increase in atmospheric CH4 concentration during recent years.
Highlights
1.1 General introductionAnthropogenic methane (CH4) emissions contribute significantly to global radiative forcing
We highlight the results of the biogeochemical modelling of natural net CH4 exchange using the LPJ dynamical global vegetation model
Since the attribution to different source types is quite ambiguous on a global scale, we propose two scenarios that satisfy regional averages of local flux rates and the global CH4 budget (Appendix A)
Summary
Anthropogenic methane (CH4) emissions contribute significantly to global radiative forcing. 1750 AD), anthropogenic CH4 emissions have produced. A current forcing of 0.48 W m−2 (Denman et al, 2007). This corresponds to ∼ 30 % of the radiative forcing from CO2 (1.66 W m−2). The goal of this study is to identify trends and variability of global net CH4 exchange from ecosystems over the last two decades. We make a first attempt to attribute the variability of CH4 exchange to different categories of ecosystems on the global scale. Biogeochemical processes leading to CH4 exchanges are commonly treated identically as emissions from “wetlands”. We try to assess these processes individually by modelling the biogeochemical cycle of the land biosphere, the atmospheric chemistry and transport of emitted CH4, and the uncertainties associated with these processes
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