Recent studies suggest that tree-mediated methane emissions have the potential to offset the soil methane sink and may convert the forest from a net sink to a net source. However, tree-mediated CH₄ emissions represent an uncertain pathway of the total CH₄ flux from forested ecosystems. We measured the stem CH₄ fluxes from Alnus japonica in a riparian wetland of a temperate forest for a year using automated chambers. Three mature Alnus japonica trees grown naturally in the riparian wetland were selected for this study. Dissolved CH₄ concentrations in groundwater at two depths beneath each tree were measured biweekly. The sap flux for each tree was measured with Granier-type sensors.

The stem CH₄ fluxes seasonally vary, showing summertime maxima and wintertime minima. The stem CH₄ fluxes positively correlate with dissolved CH₄ concentration in groundwater beneath the trees. In addition, stem CH₄ emissions were observed when the sap flux diminished during the defoliation period. These results indicate that CH₄ in the rhizosphere is transported in the gaseous form through intercellular space in trees. On the other hand, CH₄ transport by sap flux also likely exists based on our observations; stem CH₄ fluxes showed diurnal variation. We also observed that rainfall caused a clear increase in the stem CH₄ emissions. Temporal changes in the groundwater flow paths by rainfall would have affected the belowground CH₄ concentrations and the stem CH₄ flux. Dynamic changes in soil environmental conditions (soil temperature, groundwater flow) controlled dissolved CH₄ concentrations in groundwater, thus, stem CH₄ flux. Our findings highlight the need for continuous stem CH₄ flux measurements to better understand the controlling factors and future response of CH₄ dynamics in forests to climate change.