Heat-Wave Effects on Oxygen, Nutrients, and Phytoplankton Can Alter Global Warming Potential of Gases Emitted from a Small Shallow Lake

Bartosiewicz, Maciej; Laurion, Isabelle; Clayer, François; Maranger, Roxane

doi:10.1021/acs.est.5b06312

Cited by 53 publications

(47 citation statements)

References 75 publications

(103 reference statements)

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“…High temperatures amplified CH 4 emissions (Sepulveda‐Jauregui et al., ), which led to markedly higher amounts of CH 4 stored and emitted from the basins in the hotter summer of 2014 with a clear correlation between CH 4 emissions and temperature. Similar responses to regional temperature have been shown in ponds, in small shallow, and medium‐sized lakes (Bartosiewicz, Laurion, & Macintyre, ; Bartosiewicz et al., ; Encinas Fernández et al., ; Liikanen, Huttunen, Valli, & Martikainen, ; Miettinen et al., ; Natchimuthu et al., ; Room et al., ) and in enclosure experiments (Audet et al., ; Yvon‐Durocher et al., ), suggesting that in predicted warming scenarios, an increase in carbon greenhouse gas emissions can be expected in lake ecosystems regardless of DOC inputs and their biogeochemical effects in the water column (e.g., in stratification, temperature regimes, pH, microbial metabolism and CO 2 dynamics).…”

Section: Discussionsupporting

confidence: 63%

Assessment of methane and carbon dioxide emissions in two sub‐basins of a small acidic bog lake artificially divided 30 years ago

et al. 2018

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Although lakes are important sources of methane (CH4) and carbon dioxide (CO2) to the atmosphere contributing to global warming, their CH4 and CO2 emissions are rarely assessed. In particular, increasing inputs of terrestrial dissolved organic carbon (DOC) may affect gas dynamics and alter seasonal changes in gas production. Here, we analysed variations in CH4 and CO2 dynamics in sub‐basins of an acidic bog lake, which was artificially divided into four quarters three decades ago, leading to divergence in water chemistry and biology. In the divided lake, only the south‐west basin (SW) received DOC inputs from an adjacent peat bog, while the north‐east basin (NE) was hydrologically disconnected. A year‐long determination of CH4 and CO2 production and emission patterns in the two contrasting basins exposed the indirect mechanisms by which DOC supply exercised control on greenhouse gas dynamics in this shallow lake. In both basins, dissolved CH4 was negatively correlated with dissolved oxygen (O2) through the water column, suggesting that aerobic methanotrophy is an important regulator of CH4 emissions in this lake. In contrast, the amount of CO2 stored in oxic and anoxic layers was not significantly different between the basins, suggesting that O2 is not the most important driver of dissolved CO2. Estimated total CH4 and CO2 emissions were 2.1 and 1.7 times lower in the NE basin than in the SW basin, with major CH4 and CO2 emissions occurring during the fall turnover. The differences in CH4 and CO2 emissions suggest that the hydro‐physical properties, namely seasonal temperature, the duration of stratification and O2 availability, are the main drivers of CH4 and CO2 emissions to the atmosphere from small shallow lakes under the influence of DOC inputs under global warming pressure.

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Section: Discussionsupporting

confidence: 63%

Assessment of methane and carbon dioxide emissions in two sub‐basins of a small acidic bog lake artificially divided 30 years ago

et al. 2018

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“…Furthermore, HWs might alter CH 4 emission pathways as was observed in a Canadian shallow lake where the dominant pathway of CH 4 emission shifted from ebullition to diffusion during a summer HW (Bartosiewicz et al, 2016). HWs can promote water stratification in lakes (Jankowski et al, 2006;Jeppesen, Sondergaard, Lauridsen, Liboriussen, et al, 2012) and a study of a Canadian shallow lake found that GHGs produced in the sediment were trapped in the colder water of the hypolimnion (Bartosiewicz et al, 2016). N 2 O and CH 4 fluxes might be affected by diel dynamics in light, pH (related to changes in primary production) and temperature (K€ aki, Ojala, & Kankaala, 2001).…”

Section: Discussionmentioning

confidence: 99%

“…"0" means that the HW 1 treatment did not differ significantly from the HW 2 treatment, that is, the effect of the HW did not differ from the effect of the ambient summer temperature (see "Materials and methods" and , 2014;Michaletz, Cheng, Kerkhoff, & Enquist, 2014) and for GHG processes in shallow lakes (Bartosiewicz et al, 2016;Davidson et al, 2015). It might be at least partially explained by the effect of changes in biotic interactions related to warming overriding the direct metabolism-related temperature effect on GHGs, at least for a moderate increase in temperature.…”

Section: Discussionmentioning

confidence: 99%

“…Plant-mediated fluxes across the water-air interface did not occur in our study as only submerged plants were present in the mesocosms. Consequently, when shallow lakes stratify, GHG might be released only when the water column becomes fully mixed again (Bartosiewicz et al, 2016). Although diel variation in gas fluxes is probably of significance, we assumed that this would bear no impact on our conclusions since we aimed at comparing fluxes across the different treatments and did not have focus on absolute fluxes.…”

Section: Discussionmentioning

confidence: 99%

“…HWs can severely affect the thermal regime of lakes; by way of example, the 2003 summer HW in Europe resulted in strong oxygen depletion of the hypolimnion of two deep lakes in Switzerland (Jankowski, Livingstone, B€ uhrer, Forster, & Niederhauser, 2006). Despite these adverse trends, the effect of such potentially stressful climatic events on GHG emissions is largely unknown (Bartosiewicz, Laurion, Clayer, & Maranger, 2016). Despite these adverse trends, the effect of such potentially stressful climatic events on GHG emissions is largely unknown (Bartosiewicz, Laurion, Clayer, & Maranger, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Heat‐wave effects on greenhouse gas emissions from shallow lake mesocosms

et al. 2017

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Shallow lakes are a key component of the global carbon cycle. It is, therefore, important to know how shallow lake ecosystems will respond to the current climate change. Global warming affects not only average temperatures, but also the frequency of heat waves (HW). The impact of extreme events on ecosystems processes, particularly greenhouse gas (GHG) emissions, is uncertain. Using the world's longest‐running shallow lake experiment, we studied the effects of a simulated summer HW on the fluxes of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O). The experimental mesocosms had been exposed to different temperature treatments and nutrient loading for 11 years prior to the artificial HW. In general, there was an increase in total GHG emissions during the 1‐month artificial HW, with a significant increase in CO2, CH4 and N2O being observed in the shallow lake mesocosms. No significant effect of the HW on CO2 emissions could be traced, though, in the mesocosms with high nutrient levels. Furthermore, the data suggested that in addition to the direct effect of increased temperature on metabolic processes during the HW, biotic interactions exerted a significant control of GHG emissions. For example, at low nutrient levels, increased CO2 emissions were associated with low macrophyte abundance, whereas at high nutrient levels, decreased phytoplankton abundance was linked to increased emissions of CO2 and CH4. In contrast to the observable heat‐wave effect, no clear general effect of the long‐term temperature treatments could be discerned over the summer, likely because the potential effects of the moderate temperature increase, applied as a press disturbance, were overridden by biotic interactions. This study demonstrates that the role of biotic interactions needs to be considered within the context of global warming on ecosystem processes.

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Carbon emission from thermokarst lakes in NE European tundra

Zabelina

Shirokova

Klimov

et al. 2020

Limnology & Oceanography

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Emission of greenhouse gases (GHGs) from inland waters is recognized as highly important and an understudied part of the terrestrial carbon (C) biogeochemical cycle. These emissions are still poorly quantified in subarctic regions that contain vast amounts of surface C in permafrost peatlands. This is especially true in NE European peatlands, located within sporadic to discontinuous permafrost zones which are highly vulnerable to thaw. Initial measurements of C emissions from lentic waters of the Bolshezemelskaya Tundra (BZT; 200,000 km 2) demonstrated sizable CO 2 and CH 4 concentrations and fluxes to the atmosphere in 98 depressions, thaw ponds, and thermokarst lakes ranging from 0.5 × 10 6 to 5 × 10 6 m 2 in size. CO 2 fluxes decreased by an order of magnitude as waterbody size increased by > 3 orders of magnitude while CH 4 fluxes showed large variability unrelated to lake size. By using a combination of Landsat-8 and GeoEye-1 images, we determined lakes cover 4% of BZT and thus calculated overall C emissions from lentic waters to be 3.8 AE 0.65 Tg C yr −1 (99% C-CO 2 , 1% C-CH 4), which is two times higher than the lateral riverine export. Large lakes dominated GHG emissions whereas small thaw ponds had a minor contribution to overall water surface area and GHG emissions. These data suggest that, if permafrost thaw in NE Europe results in disappearance of large thermokarst lakes and formation of new small thaw ponds and depressions, GHG emissions from lentic waters in this region may decrease.

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Heat-Wave Effects on Oxygen, Nutrients, and Phytoplankton Can Alter Global Warming Potential of Gases Emitted from a Small Shallow Lake

Cited by 53 publications

References 75 publications

Assessment of methane and carbon dioxide emissions in two sub‐basins of a small acidic bog lake artificially divided 30 years ago

Assessment of methane and carbon dioxide emissions in two sub‐basins of a small acidic bog lake artificially divided 30 years ago

Heat‐wave effects on greenhouse gas emissions from shallow lake mesocosms

Carbon emission from thermokarst lakes in NE European tundra

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