Plant-mediated CH4 transport and C gas dynamics quantified in-situ in a Phalaris arundinacea-dominant wetland

Northern peatland methane (CH₄) budgets are important for global CH₄ emissions. This study aims to determine the ecosystem CH₄ budget and specifically to quantify the importance of Phalaris arundinacea by using different chamber techniques in a temperate wetland. Annually, roughly 70?±?35% of ecosystem CH₄ emissions were plant-mediated, but data show no evidence of significant diurnal variations related to convective gas flow regardless of season or plant growth stages. Therefore, despite a high percentage of arenchyma, P. arundinacea-mediated CH₄ transport is interpreted to be predominantly passive. Thus, diurnal variations are less important in contrast to wetland vascular plants facilitating convective gas flow. Despite of plant-dominant CH₄ transport, net CH₄ fluxes were low (–?0.005–0.016 μmol m^?2 s^?1) and annually less than 1% of the annual C-CO₂ assimilation. This is considered a result of an effective root zone oxygenation resulting in increased CH₄ oxidation in the rhizosphere at high water levels. This study shows that although CH₄, having a global warming potential 25 times greater than CO₂, is emitted from this P. arundinacea wetland, less than 9% of the C sequestered counterbalances the CH₄ emissions to the atmosphere. It is concluded that P. arundinacea-dominant wetlands are an attractive C-sequestration ecosystem.