On the methane paradox: Transport from shallow water zones rather than in situ methanogenesis is the major source of CH<sub>4</sub> in the open surface water of lakes

Fernández, Jorge Encinas; Peeters, Frank; Hofmann, Hilmar

doi:10.1002/2016jg003586

Cited by 74 publications

(53 citation statements)

References 38 publications

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“…convection (Farmer, 1975;Jonas et al, 2003;Mironov et al, 2002) and downslope gravity currents, the latter originating from differential heating in the shallows (Kenney, 1996;Kirillin et al, 2015). In lakes, these currents transport heat and biogeochemical tracers between nearshore and the interior basin (Brothers et al, 2017;Encinas Fernández et al, 2016;Farrow, 2004), supporting the biogeochemical connectivity between littoral and pelagic zones. Under-ice gravity currents have been observed, and their transport has been implicated in the basin-scale thermal structure and circulation of polar lakes (Cortés & MacIntyre, 2019;Kirillin et al, 2015).…”

Section: Introductionmentioning

confidence: 86%

Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Ulloa

Winters

Wüest

et al. 2019

Geophysical Research Letters

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In ice-covered lakes, penetrative radiation warms fluid beneath a diffusive boundary layer, thereby increasing its density and providing energy for convection in a diurnally active, deepening mixed layer. Shallow regions are differentially heated to warmer temperatures, driving turbulent gravity currents that transport warm water downslope and into the basin interior. We examine the energetics of these processes, focusing on the rate at which penetrative radiation supplies energy that is available to drive fluid motion. Using numerical simulations that resolve convective plumes, gravity currents, and the secondary instabilities leading to entrainment, we show that advective fluxes due to differential heating contribute to the evolution of the mixed layer in waterbodies with significant shallow areas. A heat balance is used to assess the relative importance of differential heating to the one-dimensional effects of radiative heating and diffusive cooling at the ice-water interface in lakes of varying morphologies. Plain Language SummaryLake ice cover is one of the essential climate variables defined by the World Meteorological Organization. Its evolution is affected by direct meteorological forcing and by ice-penetrating radiation that heats near-surface waters and excites buoyancy-driven fluid motions. Both effects regulate water-to-ice heat transfer and thus the ice melting rate. We show how the warming of under-ice water is impacted by differential heating of the lake shallows and the resultant transport and mixing. We present a scaling analysis that quantifies how the rate of under-ice, mixed-layer warming depends on geometrical properties of the lake morphology. Accounting for differential heating and lateral transport is essential for processed-based models of ice-covered waterbodies that go beyond one-dimensional balances.

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Section: Introductionmentioning

confidence: 86%

Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Ulloa

Winters

Wüest

et al. 2019

Geophysical Research Letters

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“…There have been other recent indications of nonmicrobial CH 4 production, although only at very small levels insignificant in the context of the global CH 4 budget (Table ) (Wang, Lerdau, & He, ). The presence of CH 4 in oxic zones in lakes is likely driven by the transport of dissolved CH 4 from CH 4 production areas, rather than aerobic, algae‐related CH 4 production (Encinas Fernández et al, ). However, in marine environments, CH 4 production in fully oxygenated sulfate‐rich zones (see section 2.2.2) has been directly attributed to bacterial degradation of dissolved organic matter in seawater (Repeta et al, ).…”

Section: Methane In the Global Carbon Cyclementioning

confidence: 99%

Methane Feedbacks to the Global Climate System in a Warmer World

Dean

Middelburg

Röckmann

et al. 2018

Reviews of Geophysics

431

341

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Methane (CH4) is produced in many natural systems that are vulnerable to change under a warming climate, yet current CH4 budgets, as well as future shifts in CH4 emissions, have high uncertainties. Climate change has the potential to increase CH4 emissions from critical systems such as wetlands, marine and freshwater systems, permafrost, and methane hydrates, through shifts in temperature, hydrology, vegetation, landscape disturbance, and sea level rise. Increased CH4 emissions from these systems would in turn induce further climate change, resulting in a positive climate feedback. Here we synthesize biological, geochemical, and physically focused CH4 climate feedback literature, bringing together the key findings of these disciplines. We discuss environment‐specific feedback processes, including the microbial, physical, and geochemical interlinkages and the timescales on which they operate, and present the current state of knowledge of CH4 climate feedbacks in the immediate and distant future. The important linkages between microbial activity and climate warming are discussed with the aim to better constrain the sensitivity of the CH4 cycle to future climate predictions. We determine that wetlands will form the majority of the CH4 climate feedback up to 2100. Beyond this timescale, CH4 emissions from marine and freshwater systems and permafrost environments could become more important. Significant CH4 emissions to the atmosphere from the dissociation of methane hydrates are not expected in the near future. Our key findings highlight the importance of quantifying whether CH4 consumption can counterbalance CH4 production under future climate scenarios.

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“…This phenomenon is also true for methane produced in sediment of the shallow part of a deep lake. For example, findings in German lakes showed that the ratio of the surface area of the shallow water zone to the entire lake area was a better predictor of surface methane concentration than the total surface area (Encinas Ferna´ndez et al 2016). Nevertheless, studies of the distinct methane dynamics in shallow vs. deep parts of lakes at lower latitudes are needed to confirm the robustness of their conclusion.…”

Section: Perspectivesmentioning

confidence: 99%

“…Although interactions between cyanobacteria and bacteria/archaea can result in methane production in oxic layers (Bogard et al 2014), the mechanism for this process is not fully understood (summarized in Tang et al 2016). Another controversy is whether methane produced in the oxic subsurface layers makes a large (Bogard et al 2014)o r small (Encinas Ferna´ndez et al 2016) contribution to the amount of methane emitted from the lake surface. Finally, the possible production of CH 4 under aerobic conditions (Karl et al 2008;Damm et al 2008)i n marine systems has been debated.…”

Section: Perspectivesmentioning

confidence: 99%

Integrating isotopic, microbial, and modeling approaches to understand methane dynamics in a frequently disturbed deep reservoir in Taiwan

Itoh

Kojima

et al. 2017

Ecological Research

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It has been estimated that more than 48% of global methane emissions from lakes and reservoirs occur at low latitudes (<24°). To improve this estimate, knowledge regarding underexplored ecosystems, particularly deep lakes and reservoirs in Asian monsoon regions, is needed because the magnitude of methane emissions is influenced by lake bathymetry and climatic conditions. We conducted long‐term studies beginning in 2004 at Feitsui Reservoir (FTR) in Taiwan, a subtropical monomictic system with a maximum depth of 120 m to monitor seasonal and interannual variations of three key characteristics and to understand the mechanisms underlying these variations. Key characteristics investigated were as follows: (1) the balance of primary production and heterotrophic respiration as a determinant of vertical oxygen distribution, (2) methane production at the bottom of the reservoir, oxidation in the water column, and emissions from the lake surface, and (3) the contribution of methane‐originated carbon to the pelagic food web through methane‐oxidizing bacteria (MOB). This review highlights major achievements from FTR studies integrating isotopic, microbial, and modeling approaches. Based on our findings, we proposed two conceptual models: (1) a model of methane dynamics, which addresses the differences in methane emission mechanisms between deep and shallow lakes, and (2) a spatially explicit model linking benthic methane production to the pelagic food web, which addresses the diversity of MOB metabolisms and their dependence on oxygen availability. Finally, we address why long‐term studies of subtropical lakes and reservoirs are important for better understanding the effects of climate on low‐ to mid‐latitude ecosystems.

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On the methane paradox: Transport from shallow water zones rather than in situ methanogenesis is the major source of CH₄ in the open surface water of lakes

Cited by 74 publications

References 38 publications

Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Methane Feedbacks to the Global Climate System in a Warmer World

Integrating isotopic, microbial, and modeling approaches to understand methane dynamics in a frequently disturbed deep reservoir in Taiwan

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On the methane paradox: Transport from shallow water zones rather than in situ methanogenesis is the major source of CH4 in the open surface water of lakes

Cited by 74 publications

References 38 publications

Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Methane Feedbacks to the Global Climate System in a Warmer World

Integrating isotopic, microbial, and modeling approaches to understand methane dynamics in a frequently disturbed deep reservoir in Taiwan

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On the methane paradox: Transport from shallow water zones rather than in situ methanogenesis is the major source of CH₄ in the open surface water of lakes