Abstract
Inland waters are the largest natural source of methane (CH4) to the atmosphere, yet the contribution from small streams to this flux is not clearly defined. To fully understand CH4 emissions from streams and rivers, we must consider the relative importance of CH4 emission pathways, the prominence of microbially-mediated production and oxidation of CH4, and the isotopic signature of emitted CH4. Here, we construct a complete CH4 emission budgets for four lowland headwater streams by quantifying diffusive CH4 emissions and comparing them to previously published rates of ebullitive emissions. We also examine the isotopic composition of CH4 along with the sediment microbial community to investigate production and oxidation across the streams. We find that all four streams are supersaturated with respect to CH4 with diffusive emissions accounting for approximately 78–100% of total CH4 emissions. Isotopic and microbial data suggest CH4 oxidation is prevalent across the streams, depleting approximately half of the dissolved CH4 pool before emission. We propose a conceptual model of CH4 production, oxidation, and emission from small streams, where the dominance of diffusive emissions is greater compared to other aquatic ecosystems, and the impact of CH4 oxidation is observable in the emitted isotopic values. As a result, we suggest the CH4 emitted from small streams is isotopically heavy compared to lentic ecosystems. Our results further demonstrate streams are important components of the global CH4 cycle yet may be characterized by a unique pattern of cycling and emission that differentiate them from other aquatic ecosystems.
Highlights
Since the start of the industrial revolution, atmospheric concentrations of methane (CH4) have increased nearly threefold (Saunois et al, 2020)
Our results suggest CH4 emission and isotopic patterns in small streams may be unique amongst aquatic ecosystems, and may distinguish how small streams should be included in global CH4 models
This study demonstrates how small streams can emit CH4 at similar rates to other aquatic ecosystems on a per area basis, but with distinct isotopic signatures compared to lentic systems
Summary
Since the start of the industrial revolution, atmospheric concentrations of methane (CH4) have increased nearly threefold (Saunois et al, 2020). This atmospheric enrichment of CH4 is caused predominantly by anthropogenic activities; aquatic ecosystems comprise roughly half of all global CH4 emissions (Rosentreter et al, 2021). Rosentreter et al (2021) estimate that streams and rivers emit approximately 30.5 Tg CH4 yr−1 globally, which represents about 20% of the total annual emissions from lakes (151 Tg CH4 yr−1) or wetlands (149 Tg CH4 yr−1; Saunois et al, 2020). More comprehensive measurements of CH4 emissions and an improved understanding of CH4 cycling are needed to accurately include streams in regional and global CH4 budgets
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