Productivity and Temperature as Drivers of Seasonal and Spatial Variations of Dissolved Methane in the Southern Bight of the North Sea

Borges, Alberto; Speeckaert, Gaëlle; Champenois, Willy; Scranton, Mary I.; Gypens, Nathalie

doi:10.1007/s10021-017-0171-7

Cited by 75 publications

(61 citation statements)

References 83 publications

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“…Thus, the emission rates reported in this study are net emissions, which represent a balance between production and consumption of the whole system. In wetlands, a clear positive correlation between emission of methane and net ecosystem production has been documented (Borges et al, ; Bridgham et al, ; Whiting & Chanton, ; Yvon‐Durocher et al ). It has also been shown that the methane production in the rhizosphere of wetland and tundra plants is to a large extent driven by recent plant photosynthates in the form of root exudates (Dorodnikov et al, ; King & Reeburgh, ; Megonigal et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…On the other hand, the photosynthetically derived oxygen that is transported to the rhizosphere by the roots of wetland plants (i.e., radial oxygen loss) can also suppress methane production (Laanbroek, 2009), and in temperate seagrasses, such a release of oxygen to the rhizosphere has been shown to also protect against sulfides and other toxins (Brodersen et al, 2015Pedersen et al, 1998). Methanogenesis is also a temperature-dependent process (Dunfield et al, 1993;Sanz-Lázaro et al, 2011;Van Bodegom & Stams, 1999;Westermann, Ahring, & Mah, 1989;Zeikus & Winfrey, 1976), and rapid changes in temperature can result in simultaneous changes in methane production (Borges et al, 2018;Chin, Lukow, & Conrad, 1999;Høj, Olsen, & Torsvik, 2008;Segers, 1998;Van Bodegom & Stams, 1999). This is partly due to a direct effect on the process, where the methane production can have a Q 10 (i.e., a relative increase in activity after an increase in temperature of 10°C) of 1.3-28 (Dunfield et al, 1993;Segers, 1998;Van Hulzen, Segers, Bodegom, & Leffelaar, 1999) and partly because of a temperature-driven shift in the composition and activity of the microbial community (Conrad, Klose, & Noll, 2009;Høj et al, 2008;Pender et al, 2004).…”

Section: Relative Importance Of Temperature and Etr On Methane Emismentioning

confidence: 99%

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Methane emission and sulfide levels increase in tropical seagrass sediments during temperature stress: A mesocosm experiment

George

Gullström

Mtolera

et al. 2020

Ecology and Evolution

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Climate change‐induced ocean warming is expected to greatly affect carbon dynamics and sequestration in vegetated shallow waters, especially in the upper subtidal where water temperatures may fluctuate considerably and can reach high levels at low tides. This might alter the greenhouse gas balance and significantly reduce the carbon sink potential of tropical seagrass meadows. In order to assess such consequences, we simulated temperature stress during low tide exposures by subjecting seagrass plants (Thalassia hemprichii) and associated sediments to elevated midday temperature spikes (31, 35, 37, 40, and 45°C) for seven consecutive days in an outdoor mesocosm setup. During the experiment, methane release from the sediment surface was estimated using gas chromatography. Sulfide concentration in the sediment pore water was determined spectrophotometrically, and the plant's photosynthetic capacity as electron transport rate (ETR), and maximum quantum yield (Fv/Fm) was assessed using pulse amplitude modulated (PAM) fluorometry. The highest temperature treatments (40 and 45°C) had a clear positive effect on methane emission and the level of sulfide in the sediment and, at the same time, clear negative effects on the photosynthetic performance of seagrass plants. The effects observed by temperature stress were immediate (within hours) and seen in all response variables, including ETR, Fv/Fm, methane emission, and sulfide levels. In addition, both the methane emission and the size of the sulfide pool were already negatively correlated with changes in the photosynthetic rate (ETR) during the first day, and with time, the correlations became stronger. These findings show that increased temperature will reduce primary productivity and increase methane and sulfide levels. Future increases in the frequency and severity of extreme temperature events could hence reduce the climate mitigation capacity of tropical seagrass meadows by reducing CO2 sequestration, increase damage from sulfide toxicity, and induce the release of larger amounts of methane.

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Section: Discussionmentioning

confidence: 99%

Section: Relative Importance Of Temperature and Etr On Methane Emismentioning

confidence: 99%

Methane emission and sulfide levels increase in tropical seagrass sediments during temperature stress: A mesocosm experiment

George

Gullström

Mtolera

et al. 2020

Ecology and Evolution

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“…In a recent study, Borges et al (2018) suggested a close coupling between eutrophication of the Belgian coastal zone and methane emissions from sediments. These authors compared methane concentrations 26 years apart and found a significant decrease in water column CH 4 concentrations, which they attribute to oligotrophication of the coastal zone during that time period.…”

Section: Outlook and Implicationsmentioning

confidence: 99%

Legacy Effects of Eutrophication on Modern Methane Dynamics in a Boreal Estuary

Myllykangas

Hietanen

Jilbert

2019

Estuaries and Coasts

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Estuaries are important conduits between terrestrial and marine aquatic systems and function as hot spots in the aquatic methane cycle. Eutrophication and climate change may accelerate methane emissions from estuaries, causing positive feedbacks with global warming. Boreal regions will warm rapidly in the coming decades, increasing the need to understand methane cycling in these systems. In this 3-year study, we investigated seasonal and spatial variability of methane dynamics in a eutrophied boreal estuary, both in the water column and underlying sediments. The estuary and the connected archipelago were consistently a source of methane to the atmosphere, although the origin of emitted methane varied with distance offshore. In the estuary, the river was the primary source of atmospheric methane. In contrast, in the adjacent archipelago, sedimentary methanogenesis fueled by eutrophication over previous decades was the main source. Methane emissions to the atmosphere from the study area were highly variable and dependent on local hydrodynamics and environmental conditions. Despite evidence of highly active methanogenesis in the studied sediments, the vast majority of the upwards diffusive flux of methane was removed before it could escape to the atmosphere, indicating that oxidative filters are presently still functioning regardless of previous eutrophication and ongoing climate change.

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“…No overall pattern of controlling factors of methane emission were revealed by Ortiz-Llorente and Alvarez-Cobelas (2012); thus, the authors concluded that local studies are vital for assessing methane emission and its controlling factors. The presence and strength of a pycnocline is especially critical in the control of methane emission, as this emission is much stronger from environments without stratification (Borges et al, 2017) than from stratified systems where MOX can consume part of the methane . Temperature is another important environmental control factor, as methane production is very temperature sensitive (i.e.…”

Section: Diffusive Methane Fluxmentioning

confidence: 99%

“…methanogenesis is higher at higher temperatures). Consequently, tropical and temperate regions would be expected to show higher methane concentrations and emissions (Borges et al, 2017;Lofton et al, 2014), while polar regions would have lower concentrations and emissions. However, as methane oxidation is only somewhat influenced by temperature, this may offset methane consumption vs. methane production in polar areas (Lofton et al, 2014), thereby resulting in lower methane concentrations overall in polar regions.…”

Section: Diffusive Methane Fluxmentioning

confidence: 99%

Methane distribution and oxidation around the Lena Delta in summer 2013

et al. 2017

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Abstract. The Lena River is one of the largest Russian rivers draining into the Laptev Sea. The predicted increases in global temperatures are expected to cause the permafrost areas surrounding the Lena Delta to melt at increasing rates. This melting will result in high amounts of methane reaching the waters of the Lena and the adjacent Laptev Sea. The only biological sink that can lower methane concentrations within this system is methane oxidation by methanotrophic bacteria. However, the polar estuary of the Lena River, due to its strong fluctuations in salinity and temperature, is a challenging environment for bacteria. We determined the activity and abundance of aerobic methanotrophic bacteria by a tracer method and by the quantitative polymerase chain reaction. We described the methanotrophic population with a molecular fingerprinting method (monooxygenase intergenic spacer analysis), as well as the methane distribution (via a headspace method) and other abiotic parameters, in the Lena Delta in September 2013.The median methane concentrations were 22 nmol L −1 for riverine water (salinity (S) < 5), 19 nmol L −1 for mixed water (5 < S < 20) and 28 nmol L −1 for polar water (S > 20). The Lena River was not the source of methane in surface water, and the methane concentrations of the bottom water were mainly influenced by the methane concentration in surface sediments. However, the bacterial populations of the riverine and polar waters showed similar methane oxidation rates (0.419 and 0.400 nmol L −1 d −1 ), despite a higher relative abundance of methanotrophs and a higher estimated diversity in the riverine water than in the polar water. The methane turnover times ranged from 167 days in mixed water and 91 days in riverine water to only 36 days in polar water. The environmental parameters influencing the methane oxidation rate and the methanotrophic population also differed between the water masses. We postulate the presence of a riverine methanotrophic population that is limited by sub-optimal temperatures and substrate concentrations and a polar methanotrophic population that is well adapted to the cold and methane-poor polar environment but limited by a lack of nitrogen. The diffusive methane flux into the atmosphere ranged from 4 to 163 µmol m 2 d −1 (median 24). The diffusive methane flux accounted for a loss of 8 % of the total methane inventory of the investigated area, whereas the methanotrophic bacteria consumed only 1 % of this methane inventory. Our results underscore the importance of measuring the methane oxidation activities in polar estuaries, and they indicate a population-level differentiation between riverine and polar water methanotrophs.

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Productivity and Temperature as Drivers of Seasonal and Spatial Variations of Dissolved Methane in the Southern Bight of the North Sea

Cited by 75 publications

References 83 publications

Methane emission and sulfide levels increase in tropical seagrass sediments during temperature stress: A mesocosm experiment

Methane emission and sulfide levels increase in tropical seagrass sediments during temperature stress: A mesocosm experiment

Legacy Effects of Eutrophication on Modern Methane Dynamics in a Boreal Estuary

Methane distribution and oxidation around the Lena Delta in summer 2013

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