Many inland waters exhibit complete or partial desiccation, or have vanished due to global change, exposing sediments to the atmosphere. Yet, data on carbon dioxide (CO 2) emissions from these sediments are too scarce to upscale emissions for global estimates or to understand their fundamental drivers. Here, we present the results of a global survey covering 196 dry inland waters across diverse ecosystem types and climate zones. We show that their CO 2 emissions share fundamental drivers and constitute a substantial fraction of the carbon cycled by inland waters. CO 2 emissions were consistent across ecosystem types and climate zones, with local characteristics explaining much of the variability. Accounting for such emissions increases global estimates of carbon emissions from inland waters by 6% (~0.12 Pg C y −1). Our results indicate that emissions from dry inland waters represent a significant and likely increasing component of the inland waters carbon cycle.
The
magnitude of diffusive carbon dioxide (CO2) and
methane (CH4) emission from man-made reservoirs is uncertain
because the spatial variability generally is not well-represented.
Here, we examine the spatial variability and its drivers for partial
pressure, gas-exchange velocity (k), and diffusive
flux of CO2 and CH4 in three tropical reservoirs
using spatially resolved measurements of both gas concentrations and k. We observed high spatial variability in CO2 and CH4 concentrations and flux within all three reservoirs,
with river inflow areas generally displaying elevated CH4 concentrations. Conversely, areas close to the dam are generally
characterized by low concentrations and are therefore not likely to
be representative for the whole system. A large share (44–83%)
of the within-reservoir variability of gas concentration was explained
by dissolved oxygen, pH, chlorophyll, water depth, and within-reservoir
location. High spatial variability in k was observed,
and kCH4 was persistently higher
(on average, 2.5 times more) than kCO2. Not accounting for the within-reservoir variability in concentrations
and k may lead to up to 80% underestimation of whole-system
diffusive emission of CO2 and CH4. Our findings
provide valuable information on how to develop field-sampling strategies
to reliably capture the spatial heterogeneity of diffusive carbon
fluxes from reservoirs.
This is the accepted version of a paper published in INLAND WATERS. This paper has been peer-reviewed but does not include the final publisher proof-corrections or journal pagination.
Reservoirs are important components of the global carbon (C) cycle (Cole et al., 2007;Tranvik et al., 2009). While reservoirs emit substantial amounts of carbon dioxide (CO 2 ) and methane (CH 4 ) to the atmosphere (
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