Mountain forests are an integral component of the global carbon cycle, playing a key role in the exchange of greenhouse gases. Methane (CH₄) is a potent greenhouse gas. Upland soils are thought to be sinks of atmospheric CH₄, but soils in riparian zones of mountain streams can potentially act as sources of CH₄, which is usually overlooked in global CH₄ budget. Thus, understanding how the landscape structure influences the direction and magnitude of CH₄ fluxes in mountain forested areas is important for accurately estimating CH₄ budget at the watershed scale.
The study site is located in the upper watershed of the Yura River in the Ashiu Experimental Forest of Kyoto University. We installed 60 soil collars at a depth of 5 cm in the soil across the landscape, with a distance of about 30 m between each. With different transects we covered the ridge, hillslope, riparian zone and wetland as part of examining the influence of topography on CH₄ fluxes. CH₄ flux was measured using cavity an enhanced absorption spectroscopy gas analyser.
We mainly observed negative net CH₄ fluxes, which means that overall the riparian zone, hillslopes and ridges were CH₄ sinks. Soil CH₄ uptake was highest mid-slope and lowest in the riparian zone and on ridges. Hotspots of CH₄ emissions were found in wetlands.
A comprehensive understanding of the relationship between CH₄ flux and landscape structure, as well as the associated controlling factors at different time scales, is necessary for the scaling up of chamber measurements of CH₄ flux and the accurate determination of CH₄ budgets in forested watershed ecosystems.