Carbon dioxide emissions from the flat bottom and shallow Nam Theun 2 Reservoir: drawdown area as a neglected pathway to the atmosphere

Deshmukh, Chandrashekhar; Guerin, Frédéric; Vongkhamsao, Axay; Pighini, Sylvie; Oudone, Phetdala; Sopraseuth, Saysoulinthone; Godon, Arnaud; Rode, W.; Guédant, P.; Oliva, Priscia; Audry, Stéphane; Zouiten, Cyril; Galy‐Lacaux, Corinne; Robain, Henri; Ribolzi, Olivier; Kansal, Arun; Chanudet, Vincent; Descloux, Stéphane; Serça, D.

doi:10.5194/bg-15-1775-2018

Cited by 18 publications

(15 citation statements)

References 62 publications

(143 reference statements)

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“…The drawdown area thus accounted for < 20% of the total reservoir area but contributed to > 80% of total reservoir CO 2 emissions upstream the dam. Our results are in line with a recent study conducted in a reservoir in Southeast Asia, which found that drawdown areas accounted for 50-75% of total annual reservoir CO 2 emission (Deshmukh et al 2018). Our findings indicate that drawdown areas are CO 2 emission hotspots in CDU reservoir, not only due to high emission rates in relation to reservoir water surface, but also because exposed sediments cover a large fraction of the total reservoir area over long periods of the year (Fig.…”

Section: Relative Contribution Of Drawdown Areas To Total Reservoir Csupporting

confidence: 92%

“…An important factor supporting enhanced CO 2 emission rates from exposed sediments is the increased microbial metabolism (e.g., enhanced enzyme activity of phenol oxidases and hydrolases) as sediment dries out (Hyojin et al 2016;Weise et al 2016). The importance of exposed sediments to reservoir carbon processing is clearly illustrated by a study in a Southeast Asian reservoir, which demonstrates that drawdown areas may contribute up to 75% of total annual CO 2 emissions (Deshmukh et al 2018). Globally, dry exposed sediments are estimated to emit ~ 200 Tg of carbon as CO 2 , which is equivalent to ~ 10% of global CO 2 emissions from inland waters (Marcé et al 2019).…”

Section: Aquatic Sciencesmentioning

confidence: 99%

“…Understanding the variability of CO 2 fluxes from drawdown areas over time and space is fundamental to support the definition of adequate sampling strategies and thus more realistic upscaling of CO 2 emissions from freshwater systems. While one study has reported limited spatial and annual variability in drawdown area CO 2 fluxes (Deshmukh et al 2018), the scarcity of data makes it difficult to draw general conclusions about spatial or temporal variability of drawdown area CO 2 emission. Here we investigate the spatial variation in CO 2 fluxes from the drawdown areas of a reservoir in southeastern Brazil.…”

Section: Aquatic Sciencesmentioning

confidence: 99%

“…Cycles of wetting-desiccation accelerate carbon losses from freshwater systems (Reverey et al 2016). Indeed, a growing number of studies in different types of aquatic ecosystems (reservoirs, intermittent streams, temporary ponds) suggest that exposed sediments emit substantially more CO 2 than adjacent water surfaces (Catalán et al 2014;Deshmukh et al 2018;Gilbert et al 2017;Gómez-Gener et al 2015;Hyojin et al 2016;Looman et al 2017;Obrador Fig. 3 Relative contribution of drawdown area (dark grey) and water surface area (light grey) to the total reservoir area of Chapéu D'Uvas (CDU) reservoir over time Fig.…”

Section: Co 2 Fluxes In Drawdown Areasmentioning

confidence: 99%

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Carbon dioxide emission from drawdown areas of a Brazilian reservoir is linked to surrounding land cover

et al. 2019

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Reservoir sediments exposed to air due to water level fluctuations are strong sources of atmospheric carbon dioxide (CO 2). The spatial variability of CO 2 fluxes from these drawdown areas are still poorly understood. In a reservoir in southeastern Brazil, we investigated whether CO 2 emissions from drawdown areas vary as a function of neighboring land cover types and assessed the magnitude of CO 2 fluxes from drawdown areas in relation to nearby water surface. Exposed sediments near forestland (average = 2733 mg C m −2 day −1) emitted more CO 2 than exposed sediments near grassland (average = 1261 mg C m −2 day −1), congruent with a difference in organic matter content between areas adjacent to forestland (average = 12.2%) and grassland (average = 10.9%). Moisture also had a significant effect on CO 2 emission, with dry exposed sediments (average water content: 13.7%) emitting on average 2.5 times more CO 2 than wet exposed sediments (average water content: 23.5%). We carried out a systematic comparison with data from the literature, which indicates that CO 2 efflux from drawdown areas globally is about an order of magnitude higher than CO 2 efflux from adjacent water surfaces, and within the range of CO 2 efflux from terrestrial soils. Our findings suggest that emissions from exposed sediments may vary substantially in space, possibly related to organic matter supply from uphill vegetation, and that drawdown areas play a disproportionately important role in total reservoir CO 2 emissions with respect to the area they cover.

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Section: Relative Contribution Of Drawdown Areas To Total Reservoir Csupporting

confidence: 92%

Section: Aquatic Sciencesmentioning

confidence: 99%

Section: Aquatic Sciencesmentioning

confidence: 99%

Section: Co 2 Fluxes In Drawdown Areasmentioning

confidence: 99%

See 2 more Smart Citations

Carbon dioxide emission from drawdown areas of a Brazilian reservoir is linked to surrounding land cover

et al. 2019

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“…) and thus some labile sedimentary carbon stores were likely converted to CO 2 via aerobic pathways and evaded to the atmosphere, resulting in a net loss of labile carbon between C1 and C2. Even relatively small drawdown areas and drying of sediments have been shown to significantly enhance carbon losses and retard subsequent methanogensis upon reflooding (Chimner and Cooper ; Knorr et al ; Deshmukh et al ), with significant alteration to the microbial community following drought events (Rees et al ). After the initial suppression of methane production during water table drawn down, reflooding events eventually cause methane concentrations to increase with the timing of recovery ranging from a matter of days to months (Boon et al ; Knorr et al ; Tyler et al ).…”

Section: Discussionmentioning

confidence: 99%

Wetland methane emissions dominated by plant‐mediated fluxes: Contrasting emissions pathways and seasons within a shallow freshwater subtropical wetland

Jeffrey

Maher

Johnston

et al. 2019

Limnology & Oceanography

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Wetlands represent the largest natural source of methane; however, very few studies have simultaneously quantified the three main atmospheric flux pathways (i.e., diffusive, ebullition, and plant‐mediated). Unlike better‐studied northern hemisphere systems, many Australian subtropical wetlands undergo extreme wet/dry oscillations, which may strongly impact methane dynamics. We assessed diurnal methane emissions of multiple pathways during three distinct seasonal events within an Australian freshwater wetland. Six‐fold higher methane emissions occurred during summer compared to autumn floods (which followed an extensive dry‐period) and winter/cool conditions. Over three seasons, diffusion represented the highest average areal fluxes (25.9 ± 73.2 mmol m−2 d−1) but were within range of fluxes through water lily aerenchyma (20.8 ± 41.5 mmol m−2 d−1). Average ebullition rates were 5.5 ± 9.7 mmol m−2 d−1. Water column CH4 displayed high spatiotemporal variability, ranging from 55.0 to 253.5 μmol L−1. Time series δ13C–CH4 isotope measurements revealed an oxidation fraction of ~ 15% at night‐time and ~ 36% during day‐time, and night‐time diffusive fluxes were consistently ~ three‐fold higher than day‐time fluxes. By aggregating seasons and weighting for changes in lily coverage, plant‐mediated fluxes accounted for ~ 59% of the annual methane emissions, whereas ebullition and diffusion each accounted for ~ 20%. The up‐scaled annual area‐weighted wetland methane flux (combined pathways) was 27.3 ± 36.7 mmol m−2 d−1. We contend that water lilies (Nymphaea sp.) are the significant carbon source, mediator, and conduit for methane fluxes in this system, and the extremely large seasonal variability of methane emissions reflect dynamic redox oscillations driven by oscillating wet and dry conditions.

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Juxtaposing the spatiotemporal drivers of sediment CO2, CH4, and N2O effluxes along ecoregional, wet-dry, and diurnal gradients

Arı

İlhan

Evrendilek

2021

Atmospheric Pollution Research

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Carbon dioxide emissions from the flat bottom and shallow Nam Theun 2 Reservoir: drawdown area as a neglected pathway to the atmosphere

Cited by 18 publications

References 62 publications

Carbon dioxide emission from drawdown areas of a Brazilian reservoir is linked to surrounding land cover

Carbon dioxide emission from drawdown areas of a Brazilian reservoir is linked to surrounding land cover

Wetland methane emissions dominated by plant‐mediated fluxes: Contrasting emissions pathways and seasons within a shallow freshwater subtropical wetland

Juxtaposing the spatiotemporal drivers of sediment CO2, CH4, and N2O effluxes along ecoregional, wet-dry, and diurnal gradients

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