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Arctic carbon may be worse than feared
Researchers find potential for methane emissions, which eclipse CO2 as risks
For some time, scientists fearing the mass release of greenhouse gases from the carbon rich, frozen soils of the Arctic have had at least one morsel of good news in their forecasts: They predicted most of the gas released would be carbon dioxide, which, though a greenhouse gas, drives warming more slowly than some other gases. Scientists obviously weren’t excited about more carbon dioxide emissions, but it was better than the alternative: methane, a shorter-lived but far harder hitting gas, which could cause faster bursts of warming.
Now even that silver lining is in doubt.
New research released on Monday suggests methane releases could be considerably more prevalent as Arctic permafrost thaws. The new research finds that in waterlogged wetland soils, where oxygen is not prevalent, tiny micro-organisms will produce a considerable volume of methane, a gas that doesn’t last in the air much more than a decade, but that has a warming effect many times that of carbon dioxide over a period of 100 years.
“What we can definitely say is that the importance of methane was underestimated until now in the carbon studies,” said Christian Knobloch, the lead author of the study in Nature Climate Change and a researcher at the Universitat Hamburg in Germany.
The reason for the divergent finding is that Knoblauch and his colleagues conducted a lengthy, more than 7 year long experiment, monitoring patches of submerged and artificially warmed soil from Siberia in the laboratory, and gradually seeing sensitive methane-producing micro-organisms become more prevalent over time.
Knoblauch contends that other studies have not examined waterlogged Arctic soils for as long, and notes that in some cases it took three years or more for the methane-generating microorganisms to really get cranking.
“What we saw is that it takes a very long time until methane starts being produced, and the study that we did is really the first one which is so long,” Knoblauch said.
The research was conducted along with colleagues from several institutions in Germany, Sweden and Russia.
So much methane was produced in the experiment that the researchers calculated that the impact of greenhouse gas emissions from wet soils, or wetlands, will be higher than from drier soils, where carbon dioxide should indeed be the top gas released. This finding, if further confirmed, could potentially reorient calculations of the overall potential of permafrost to worsen global warming over the coming century.
For instance, one major study of the permafrost warming potential, published in 2015 in the journal Nature, downplayed the potential for methane release in wet soils, saying that drier soils would be the bigger problem.
“In spite of the more potent greenhouse gas CH4, a unit of newly thawed permafrost carbon could have a greater impact on climate over a century if it thaws and decomposes within a drier, aerobic soil as compared to an equivalent amount of carbon within a waterlogged soil or sediment,” that research found. The new study would appear to contradict this.
But Knoblauch cautions that more research would have to be done in order to go from these results to a forecast for just how much methane could waft from permafrost in the coming decades. It will be important to know, for instance, how much thawed permafrost will be stuck in watery conditions versus dry ones.
One Arctic permafrost expert not involved in the research, Merritt Turetsky of the University of Guelph, praised the new study, noting the researchers had spent a long time trying to uncover the behavior of tiny methane-producing organisms in watery soil. The research, she said, could help bridge the gap between field studies of waterlogged permafrost that have indeed detected methane emissions, and laboratory studies that have seemed to downplay the importance of the gas.