Carbon emissions from inland waters may be underestimated: Evidence from European river networks fragmented by drying

River networks contribute disproportionately to the global carbon cycle. However, global estimates of carbon emissions from inland waters are based on perennial rivers, even though more than half of the world's river length is prone to drying. We quantified CO2 and CH4 emissions from flowing wa...

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Bibliographic Details
Published in:Limnology and oceanography letters 2024-10, Vol.9 (5), p.553-562
Main Authors: López‐Rojo, Naiara, Datry, Thibault, Peñas, Francisco J., Singer, Gabriel, Lamouroux, Nicolas, Barquín, José, Rodeles, Amaia A., Silverthorn, Teresa, Sarremejane, Romain, Campo, Rubén, Estévez, Edurne, Mimeau, Louise, Boyer, Frédéric, Künne, Annika, Dalvai Ragnoli, Martin, Foulquier, Arnaud
Format: Article
Language:English
Subjects:
Atmosphere
Biogeochemistry
Carbon cycle
Carbon dioxide
Carbon dioxide emissions
Creeks & streams
Drought
Drying
Earth Sciences
Ecosystems
Emissions
Environmental Sciences
Greenhouse gases
Hydrology
Inland waters
Methane
Perennial streams
Rain
Respiration
River ecology
River networks
Rivers
Sciences of the Universe
Stream flow
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Summary:River networks contribute disproportionately to the global carbon cycle. However, global estimates of carbon emissions from inland waters are based on perennial rivers, even though more than half of the world's river length is prone to drying. We quantified CO2 and CH4 emissions from flowing water and dry riverbeds across six European drying river networks (DRNs, 120 reaches) and three seasons and identified drivers of emissions using local and regional variables. Drivers of emissions from flowing water differed between perennial and non‐perennial reaches, both CO2 and CH4 emissions were controlled partly by the annual drying severity, reflecting a drying legacy effect. Upscaled CO2 emissions for the six DRNs at the annual scale revealed that dry riverbeds contributed up to 77% of the annual emissions, calling for an urgent need to include non‐perennial rivers in global estimates of greenhouse gas emissions.
ISSN:2378-2242
2378-2242
DOI:10.1002/lol2.10408