Water flow controls the spatial variability of methane emissions in a northern valley fen ecosystem
Northern peatlands are projected to be crucial in future atmospheric methane (CH 4 ) budgets and have a positive feedback on global warming. Fens receive nutrients from catchments via inflowing water and are more sensitive than bogs to variations in their ecohydrology. Yet, due to a lack of data det...
| Published in: | Biogeosciences |
|---|---|
| Main Authors: | , , , , , , , , , , |
| Format: | Article in Journal/Newspaper |
| Language: | English |
| Published: |
Copernicus Publications
2020
|
| Subjects: | |
| Online Access: | https://doi.org/10.5194/bg-17-6247-2020 https://doaj.org/article/fe1b4427733b407680cae8da8a2b80bf |
| Summary: | Northern peatlands are projected to be crucial in future atmospheric methane (CH 4 ) budgets and have a positive feedback on global warming. Fens receive nutrients from catchments via inflowing water and are more sensitive than bogs to variations in their ecohydrology. Yet, due to a lack of data detailing the impacts of moving water on microhabitats and CH 4 fluxes in fens, large uncertainties remain with respect to predicting CH 4 emissions from these sites under climate changes. We measured CH 4 fluxes with manual chambers over three growing seasons (2017–2019) at a northern boreal fen. To address the spatial variation at the site where a stream flows through the long and narrow valley fen, we established sample plots at varying distances from the stream. To link the variations in CH 4 emissions to environmental controls, we quantified water levels, peat temperature, dissolved oxygen concentration, vegetation composition, and leaf area index in combination with flux measurements during the growing season in 2019. We found that due to the flowing water, there was a higher water level, cooler peat temperatures, and more oxygen in the peat close to the stream, which also had the highest total leaf area and gross primary production (GPP) values but the lowest CH 4 emissions. CH 4 emissions were highest at an intermediate distance from the stream where the oxygen concentration in the surface peat was low but GPP was still high. Further from the stream, the conditions were drier and produced low CH 4 emissions. Our results emphasize the key role of ecohydrology in CH 4 dynamics in fens and, for the first time, show how a stream controls CH 4 emissions in a flow-through fen. As valley fens are common peatland ecosystems from the Arctic to the temperate zones, future projections of global CH 4 budgets need to take flowing water features into account. |
|---|