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Shallow lakes are potential methane factories

Combined nutrients and warming massively increase methane emissions from lakes.

2018.01.23 | Peter Bondo

[Translate to English:] Lavvandede søer kan være en stor kilde til frigivelse af metan til atmosfæren. (Foto: Ben Goldsmith).

Shallow lakes may be a serious source for methane release to the atmosphere. (Photo: Ben Goldsmith).

Den årlige frigivelse af metan (opdelt i diffusion og ophvirvling af gasbobler) ved forskellige eksperimentelle behandlinger i mesokosmos. Høje og lave næringsstofniveauer og tre temperaturniveauer – AMB er den oprindelige temperatur, ved A2 er temperaturerne øget med 2-3ºC og ved A2+ øget med 4-5ºC.

The annual mean methane emission (divided into diffusion and ebullition) from different experimental treatments within the mesocosm. High and low nutrient levels and then three temperature levels – AMB is ambient temperature, A2 is +2-3ºC and A2+ is +4-5ºC.

Abundant submerged plants may reduce the methane flux to the atmosphere. (Photo: Ben Goldsmith).

Shallow lakes in agricultural landscapes will emit significantly greater amounts of methane, mostly in the form of bubbles (ebullition) in a warmer world, which is a potential positive feedback mechanism to climate warming. 

Submerged plants are key predictors of methane ebullition. The combination of warming with the loss of plants appears to transform shallow lakes into methane bubbling machines.

These are the main findings of a study published in Nature Climate Change led by senior researcher Thomas A. Davidson, from the Lake group, Department of Bioscience and Arctic Research Centre, Aarhus University.

Methane is a potent greenhouse gas with 25 times greater warming potential than carbon dioxide.

Methane sources in shallow lakes

Shallow lakes are increasingly recognised as playing an important role in global greenhouse gas cycling. Given the number of shallow lakes globally they potentially have a large influence on atmospheric methane concentrations, which continue to rise.

Methane is released from lakes in a number of ways, both by diffusion of dissolved gas and by bubbles released from the sediments, also called ebullition.

Ebullition is not constant, but happens in episodes of bubble release, so is hard to measure accurately. As a result it is not clear how much methane is released as bubbles from lakes, nor are we sure how it will respond to the combination of climate change and nutrient enrichment.

The present study used the longest running freshwater mesocosm climate change experiment in the world to investigate how warming and eutrophication might interact to change methane ebullition in the future.

The results here were striking as they showed that the combination of increased nutrient loading and warming had a synergistic effect on the ebullition of methane. In the absence of nutrient enrichment, warming alone increased annual methane ebullition by around 50% and its relative contribution to total methane emission rose from about 50% to 75%.

In stark contrast to this, when nutrient levels were high, warming increased total methane emission by at least six fold and in some cases 17 fold, and the proportion of ebullition increased to 95% of total annual methane flux (See Figure).

Submerged plants reduce methane ebullition

Nutrient enrichment, or eutrophication, is the most common human impact on fresh waters, with all lakes in agricultural landscapes likely to be impacted.  

A feature of eutrophication in shallow lakes is the loss of biodiversity and the replacement of submerged plants by phytoplankton as the dominant primary producer.

The current study identified the abundance of submerged plants as a key predictor of methane ebullition. However, where plants were abundant, methane ebullition was reduced compared to when plants were absent, even at higher temperatures.

This suggests that through careful management of agricultural landscapes and fresh waters ensuring the proliferation of submerged plants, ebullition of methane can be minimised and in addition ecological condition and fresh water biodiversity will benefit.

Further information:

Senior researcher Thomas A. Davidson: Department of Bioscience, Aarhus University; mail: thd@bios.au.dk; tel.: +45 2832 3301.

Arctic Reserach Centre is member of Arctic Science Partnership. Read more here: http://www.asp-net.org/

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