Abstract
Methane (CH4) is a powerful greenhouse gas with ongoing efforts aiming to quantify and map emissions from natural and managed ecosystems. Wetlands play a significant role in the global CH4 budget, but uncertainties in their total emissions remain large, due to a combined lack of CH4 data and fuzzy boundaries between mapped ecosystem categories. European floodplain meadows are anthropogenic ecosystems that originated due to traditional management for hay cropping. These ecosystems are seasonally inundated by river water, and straddle the boundary between grassland and wetland ecosystems; however, an understanding of their CH4 function is lacking. Here, we established a replicated outdoor floodplain‐meadow mesocosm experiment to test how water table depth (45, 30, 15 cm below the soil surface) and plant composition affect CH4 fluxes over an annual cycle. Water table was a major controller on CH4, with significantly higher fluxes (overall mean 9.3 mg m−2 d−1) from the high (15 cm) water table treatment. Fluxes from high water table mesocosms with bare soil were low (mean 0.4 mg m−2 d−1), demonstrating that vegetation drove high emissions. Larger emissions came from high water table mesocosms with aerenchymatous plant species (e.g. Alopecurus pratensis, mean 12.8 mg m−2 d−1), suggesting a role for plant‐mediated transport. However, at low (45 cm) water tables A. pratensis mesocosms were net CH4 sinks, suggesting that there is plasticity in CH4 exchange if aerenchyma are present. Plant cutting to simulate a hay harvest had no effect on CH4, further supporting a role for plant‐mediated transport. Upscaling our CH4 fluxes to a UK floodplain meadow using hydrological modelling showed that the meadow was a net CH4 source because oxic periods of uptake were outweighed by flooding‐induced anoxic emissions. Our results show that floodplain meadows can be either small sources or sinks of CH4 over an annual cycle. Their CH4 exchange appears to respond to soil temperature, moisture status and community composition, all of which are likely to be modified by climate change, leading to uncertainty around the future net contribution of floodplain meadows to the CH4 cycle.
| Original language | English |
|---|---|
| Article number | e11147 |
| Number of pages | 12 |
| Journal | Ecology and Evolution |
| Volume | 14 |
| Issue number | 3 |
| DOIs | |
| Publication status | Published - 10 Mar 2024 |
Bibliographical note
ACKNOWLEDGEMENTSWe are grateful to Yoseph Araya who originally established the mesocosm array at the Open University, and to Sunitha Pangala for the loan of the static chamber. We thank Graham Howell, Emily Sear, Tim Barton and Martin Janes for general laboratory and field support. We thank Gustaf Granath for help with finding and obtaining information on aerenchyma, Georgia Carr for her preliminary involvement with data interpretation, and Joachim Audet for helpful discussions about CH4 emissions from wetlands on mineral soils. Thanks also go to Rothamsted Research and their farm staff, particularly Tim Parfitt, for providing the soil and estates staff at the Open University for help in setting up the study. Finally, we thank two anonymous reviewers for their thorough and constructive comments that helped to improve the manuscript. Mike Peacock acknowledges funding from Formas under projects LEAF-PAD (2020-00950) and PUDDLE-JUMP (2022-02138). Clare Lawson was funded by NERC and The Open University through a Daphne Jackson Fellowship.
Keywords
- meadow
- aerenchyma
- hydrology
- plants
- vegetation
- greenhouse gas
- wetland
- ecosystem
- water table
- methane
