Methane dynamics in different boreal lake types

Juutinen, Sari; Rantakari, Miitta; Kortelainen, Pirkko; Huttunen, Jari T.; Larmola, Tuula; Alm, Jukka; Silvola, Jouko; Martikainen, P.J.

doi:10.5194/bg-6-209-2009

Cited by 206 publications

(284 citation statements)

References 45 publications

(89 reference statements)

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“…Methane (CH 4 ) emissions from freshwater environments are expected to increase with warming climates (Juutinen et al, 2009;Yvon-Durocher et al, 2011Tan and Zhuang 2015a, b) but quantitative modeled projections of emissions are poorly constrained (Bastviken et al, 2011;Rasilo et al, 2015;Sepulveda-Jauregui et al, 2015;Tan et al, 2015). Observations of seasonal and annual lake CH 4 dynamics in the Arctic are necessary to define source estimates in models and understand the impact warming may have on greenhouse gas emissions.…”

Section: Introductionmentioning

confidence: 99%

“…Observations of seasonal and annual lake CH 4 dynamics in the Arctic are necessary to define source estimates in models and understand the impact warming may have on greenhouse gas emissions. Currently, in the Arctic, small lakes (surface area < 10 km 2 ) are abundant (Downing, 2010;Downing et al, 2006) and emit substantially more CH 4 per unit area than larger lakes (Bastviken et al, 2004;Cole et al, 2007;Juutinen et al, 2009;Wik et al, 2016), and seasonal variability in CH 4 emissions are influenced by energy input and organic carbon availability (Tan et al, 2015). However, climate change will lead to variations in heat balance, temperature profiles, and vertical mixing in lakes (Jankowski et al, 2006;MacIntyre et al, 2009;Hinkel et al, 2012;Butcher et al, 2015), causing many variations to both lake structure (Livingstone 2003;Coats et al, 2006) and CH 4 dynamics.…”

Section: Introductionmentioning

confidence: 99%

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Exceptional summer warming leads to contrasting outcomes for methane cycling in small Arctic lakes of Greenland

2017

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Abstract. In thermally stratified lakes, the greatest annual methane emissions typically occur during thermal overturn events. In July of 2012, Greenland experienced significant warming that resulted in substantial melting of the Greenland Ice Sheet and enhanced runoff events. This unusual climate phenomenon provided an opportunity to examine the effects of short-term natural heating on lake thermal structure and methane dynamics and compare these observations with those from the following year, when temperatures were normal. Here, we focus on methane concentrations within the water column of five adjacent small lakes on the icefree margin of southwestern Greenland under open-water and ice-covered conditions from 2012-2014. Enhanced warming of the epilimnion in the lakes under open-water conditions in 2012 led to strong thermal stability and the development of anoxic hypolimnia in each of the lakes. As a result, during open-water conditions, mean dissolved methane concentrations in the water column were significantly (p < 0.0001) greater in 2012 than in 2013. In all of the lakes, mean methane concentrations under ice-covered conditions were significantly (p < 0.0001) greater than under open-water conditions, suggesting spring overturn is currently the largest annual methane flux to the atmosphere. As the climate continues to warm, shorter ice cover durations are expected, which may reduce the winter inventory of methane and lead to a decrease in total methane flux during ice melt. Under openwater conditions, greater heat income and warming of lake surface waters will lead to increased thermal stratification and hypolimnetic anoxia, which will consequently result in increased water column inventories of methane. This stored methane will be susceptible to emissions during fall overturn, which may result in a shift in greatest annual efflux of methane from spring melt to fall overturn. The results of this study suggest that interannual variation in ground-level air temperatures may be the primary driver of changes in methane dynamics because it controls both the duration of ice cover and the strength of thermal stratification.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Exceptional summer warming leads to contrasting outcomes for methane cycling in small Arctic lakes of Greenland

2017

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“…Numerous processes were found to proceed faster in small aquatic systems than in larger ones. Sequestration rates of organic carbon (Downing, 2010;Downing et al, 2008), the concentrations of CH 4 , CO 2 , and dissolved organic carbon (DOC) in the water column (Bastviken et al, 2004;Juutinen et al, 2009;Kelly et al, 2001;Kortelainen et al, 2006;Xenopoulos et al, 2003), and CH 4 and CO 2 emissions from the water to the atmosphere increase with decreasing lake size (Juutinen et al, 2009;Kortelainen et al, 2006;Michmerhuizen et al, 1996;Repo et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Summer fluxes of methane and carbon dioxide from a pond and floating mat in a continental Canadian peatland

et al. 2016

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Abstract. Ponds smaller than 10 000 m2 likely account for about one-third of the global lake perimeter. The release of methane (CH4) and carbon dioxide (CO2) from these ponds is often high and significant on the landscape scale. We measured CO2 and CH4 fluxes in a temperate peatland in southern Ontario, Canada, in summer 2014 along a transect from the open water of a small pond (847 m2) towards the surrounding floating mat (5993 m2) and in a peatland reference area. We used a high-frequency closed chamber technique and distinguished between diffusive and ebullitive CH4 fluxes. CH4 fluxes and CH4 bubble frequency increased from a median of 0.14 (0.00 to 0.43) mmol m−2 h−1 and 4 events m−2 h−1 on the open water to a median of 0.80 (0.20 to 14.97) mmol m−2 h−1 and 168 events m−2 h−1 on the floating mat. The mat was a summer hot spot of CH4 emissions. Fluxes were 1 order of magnitude higher than at an adjacent peatland site. During daytime the pond was a net source of CO2 equivalents to the atmosphere amounting to 0.13 (−0.02 to 1.06) g CO2 equivalents m−2 h−1, whereas the adjacent peatland site acted as a sink of −0.78 (−1.54 to 0.29) g CO2 equivalents m−2 h−1. The photosynthetic CO2 uptake on the floating mat did not counterbalance the high CH4 emissions, which turned the floating mat into a strong net source of 0.21 (−0.11 to 2.12) g CO2 equivalents m−2 h−1. This study highlights the large small-scale variability of CH4 fluxes and CH4 bubble frequency at the peatland–pond interface and the importance of the often large ecotone areas surrounding small ponds as a source of greenhouse gases to the atmosphere.

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“…Increased N-deposition in concert with elevated export of DOM may promote export of N 2 O (Hong et al 2015). For lakes in agricultural systems, increased productivity due to increased nutrient inputs from the catchment may promote the net efflux of CH 4 and N 2 O (Juutinen et al 2009;Hong et al 2015), while the net impact of the CO 2 -balance will also depend on lake morphometry and stratification and so is harder to predict.…”

Section: Greenhouse Gases and Heterotrophymentioning

confidence: 99%

“…Increased loads of DOM in boreal lakes would also promote anoxia in the deeper water layers, which promotes CH 4 production and its net flux to the atmosphere (Juutinen et al 2009). Increased N-deposition in concert with elevated export of DOM may promote export of N 2 O (Hong et al 2015).…”

Section: Greenhouse Gases and Heterotrophymentioning

confidence: 99%

Environmental Impacts—Lake Ecosystems

Adrian

Hessen

Blenckner

et al. 2016

Regional Climate Studies

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The North Sea region contains a vast number of lakes; from shallow, highly eutrophic water bodies in agricultural areas to deep, oligotrophic systems in pristine high-latitude or highaltitude areas. These freshwaters and the biota they contain are highly vulnerable to climate change. As largely closed systems, lakes are ideally suited to studying climate-induced effects via changes in ice cover, hydrology and temperature, as well as via biological communities (phenology, species and size distribution, food-web dynamics, life-history traits, growth and respiration, nutrient dynamics and ecosystem metabolism). This chapter focuses on change in natural lakes and on parameters for which their climate-driven responses have major impacts on ecosystem properties such as productivity, community composition, metabolism and biodiversity. It also points to the importance of addressing different temporal scales and variability in driving and response variables along with threshold-driven responses to environmental forces. Exceedance of critical thresholds may result in abrupt changes in particular elements of an ecosystem. Modelling climate-driven physical responses like ice-cover duration, stratification periods and thermal profiles in lakes have shown major advances, and the chapter provide recent achievements in this field for northern lakes. Finally, there is a tentative summary of the level of certainty for key climatic impacts on freshwater ecosystems.

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Methane dynamics in different boreal lake types

Cited by 206 publications

References 45 publications

Exceptional summer warming leads to contrasting outcomes for methane cycling in small Arctic lakes of Greenland

Exceptional summer warming leads to contrasting outcomes for methane cycling in small Arctic lakes of Greenland

Summer fluxes of methane and carbon dioxide from a pond and floating mat in a continental Canadian peatland

Environmental Impacts—Lake Ecosystems

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