Estimates of reservoir methane emissions based on a spatially balanced probabilistic‐survey

Beaulieu, Jake J.; McManus, Michael G.; Nietch, Christopher T.

doi:10.1002/lno.10284

Cited by 60 publications

(81 citation statements)

References 48 publications

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“…By comparison, ebullition at transects T2 and T3, which are just downstream of FCR's primary inflow, was driven by variables characteristic of riverine and transitional sites in larger reservoirs (Beaulieu et al, ). Ebullition rates at both T2 and T3 sites were driven by a negative association with inflow discharge, and ebullition at T2 also had a positive association with SWI temperature.…”

Section: Discussionmentioning

confidence: 99%

“…Within reservoirs, CH 4 ebullition and diffusion rates can vary substantially along a longitudinal gradient from the upstream areas near the major inflows to the downstream areas near the dam (Beaulieu et al, , ; Huang et al, ; Sobek et al, ; Tušer et al, ). Ebullition is generally highest in shallow areas upstream, with much lower (but still detectable) rates in downstream areas (Beaulieu et al, , ). Similarly, studies have also demonstrated that the highest diffusion rates occur in shallow upstream sites and decrease toward the deeper sites in larger reservoirs (Beaulieu et al, ; Yang et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…Ebullition is generally highest in shallow areas upstream, with much lower (but still detectable) rates in downstream areas (Beaulieu et al, , ). Similarly, studies have also demonstrated that the highest diffusion rates occur in shallow upstream sites and decrease toward the deeper sites in larger reservoirs (Beaulieu et al, ; Yang et al, ). This longitudinal heterogeneity has been well documented in large reservoirs (surface area > 0.5 km 2 ; DelSontro et al, ; Demarty et al, ; Marcelino et al, 2015; Soumis et al, ; Tušer et al, ), but it remains unknown how variable CH 4 emissions are on a longitudinal gradient within small reservoirs (surface area < 0.5 km 2 ), which may exhibit less predictable reservoir zonation because of their size.…”

Section: Introductionmentioning

confidence: 99%

“…Similar to ebullition, diffusion rates are also influenced by multiple factors that can vary spatially (Beaulieu et al, ). For example, increasing near‐surface turbulence and increasing winds can increase the magnitude of CH 4 diffusing across the air‐water interface (Bastviken et al, ; Poindexter et al, ; Poindexter & Variano, ; Yang et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…Quantifying ecosystem‐scale CH 4 emission rates in combination with their drivers is difficult because of spatial heterogeneity in environmental variables, which necessitates extensive spatial sampling to avoid biased estimates (Beaulieu et al, ; Wik et al, ). Previous studies that have estimated spatial variation in the drivers of CH 4 emissions in reservoirs have primarily been conducted in larger reservoirs (Deemer et al, ).…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

The Magnitude and Drivers of Methane Ebullition and Diffusion Vary on a Longitudinal Gradient in a Small Freshwater Reservoir

et al. 2020

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Key Points CH4 ebullition rates decreased by 98% and CH4 diffusion decreased by 32% on a longitudinal gradient from reservoir inflow to dam Ebullition was driven by physical variables upstream and phytoplankton downstream; diffusion was most related to phytoplankton Despite large variation in CH4 emissions longitudinally, time series models well captured the dynamics of emissions from a small reservoir

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

The Magnitude and Drivers of Methane Ebullition and Diffusion Vary on a Longitudinal Gradient in a Small Freshwater Reservoir

et al. 2020

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Response of eutrophication and water quality drivers on greenhouse gas emissions in lakes of China: A critical analysis

et al. 2022

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Lakes, especially shallow lakes, contribute disproportionately to greenhouse gas (GHG; particularly CO2 and CH4) emissions and have received global attention due to their high potential to contribute to global warming and future climate change. Recent studies have identified eutrophication as a critical factor in GHG emissions. However, the role of lake trophic state index (TSI) and the impact of important water quality parameters (WQP) such as pH, Chl‐a, total nitrogen, total phosphorus and organic carbon on GHG emissions are still a subject of debate and an area of intense research. To further understand the relationship between GHG and lake eutrophication, datasets (GHG and WQP) from the scientific literature have been compiled, and statistical analyses of these secondary data were performed to determine the influence of eutrophication on GHG emissions. In this review, GHG emissions from Chinese lakes are quantified, and the important factors affecting these emissions are analysed systematically. The statistical analysis reveals that chlorophyll a and carbon (as TOC) are the key factors of lake eutrophication and have a significant effect on the GHG potential (mainly CH4 fluxes). In addition, the proposed mitigation measures could serve as a guide for scientists and young researchers to reduce future climatic risks.

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Methane emissions from oceans, coasts, and freshwater habitats: New perspectives and feedbacks on climate

Hamdan

Wickland

2016

Limnology & Oceanography

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Methane is a powerful greenhouse gas, and atmospheric concentrations have risen 2.5 times since the beginning of the Industrial age. While much of this increase is attributed to anthropogenic sources, natural sources, which contribute between 35% and 50% of global methane emissions, are thought to have a role in the atmospheric methane increase, in part due to human influences. Methane emissions from many natural sources are sensitive to climate, and positive feedbacks from climate change and cultural eutrophication may promote increased emissions to the atmosphere. These natural sources include aquatic environments such as wetlands, freshwater lakes, streams and rivers, and estuarine, coastal, and marine systems. Furthermore, there are significant marine sediment stores of methane in the form of clathrates that are vulnerable to mobilization and release to the atmosphere from climate feedbacks, and subsurface thermogenic gas which in exceptional cases may be released following accidents and disasters (North Sea blowout and Deepwater Horizon Spill respectively). Understanding of natural sources, key processes, and controls on emission is continually evolving as new measurement and modeling capabilities develop, and different sources and processes are revealed. This special issue of Limnology and Oceanography gathers together diverse studies on methane production, consumption, and emissions from freshwater, estuarine, and marine systems, and provides a broad view of the current science on methane dynamics of aquatic ecosystems. Here, we provide a general overview of aquatic methane sources, their contribution to the global methane budget, and key uncertainties. We then briefly summarize the contributions to and highlights of this special issue.

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Estimates of reservoir methane emissions based on a spatially balanced probabilistic‐survey

Cited by 60 publications

References 48 publications

The Magnitude and Drivers of Methane Ebullition and Diffusion Vary on a Longitudinal Gradient in a Small Freshwater Reservoir

The Magnitude and Drivers of Methane Ebullition and Diffusion Vary on a Longitudinal Gradient in a Small Freshwater Reservoir

Response of eutrophication and water quality drivers on greenhouse gas emissions in lakes of China: A critical analysis

Methane emissions from oceans, coasts, and freshwater habitats: New perspectives and feedbacks on climate

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