posted on 2022-07-12, 20:05authored byShoji D. Thottathil, Paula C. J. Reis, Yves T. Prairie
Methanogenesis is traditionally considered as a strictly
anaerobic
process. Recent evidence suggests instead that the ubiquitous methane
(CH4) oversaturation found in freshwater lakes is sustained,
at least partially, by methanogenesis in oxic conditions. Although
this paradigm shift is rapidly gaining acceptance, the magnitude and
regulation of oxic CH4 production (OMP) have remained ambiguous.
Based on the summer CH4 mass balance in the surface mixed
layer (SML) of five small temperate lakes (surface area, SA, of 0.008–0.44
km2), we show that OMP (range of 0.01 ± 0.01 to 0.52
± 0.04 μmol L–1 day–1) is linked to the concentrations of chlorophyll-a, total phosphorus, and dissolved organic carbon. The stable carbon
isotopic mass balance of CH4 (δ13C-CH4) indicates direct photoautotrophic release as the most likely
source of oxic CH4. Furthermore, we show that the oxic
CH4 contribution to the SML CH4 saturation and
emission is an inverse function of the ratio of the sediment area
to the SML volume in lakes as small as 0.06 km2. Given
that global lake CH4 emissions are dominated by small lakes
(SA of <1 km2), the large contribution of oxic CH4 production (up to 76%) observed in this study suggests that
OMP can contribute significantly to global CH4 emissions.