Thursday, February 20, 2025

‘Glacial fracking’: A hidden source of Arctic greenhouse gas emissions

Gabrielle Kleber and Leonard Magerl, postdoctoral researchers at iC3, have discovered that Arctic glaciers are leaking significant amounts of methane, a potent greenhouse gas.

UiT The Arctic University of Norway

Cabin on Svalbard — image:
*Gabrielle and Leonard lived in this remote cabin on Svalbard for three summers, staying close to Vallåkrabreen while conducting their study.*
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Credit: Leonard Magerl / iC3 / UiT

Gabrielle Kleber and Leonard Magerl, postdoctoral researchers at iC3, have discovered that Arctic glaciers are leaking significant amounts of methane, a potent greenhouse gas.

They found that glacial melt rivers and groundwater springs are transporting large volumes of methane from beneath the ice to the atmosphere. This previously unrecognised process could contribute to Arctic climate feedbacks, accelerating global warming.

iC3 – Centre for ice, Cryosphere, Carbon and Climate is a Centre of Excellence at UiT The Arctic university of Norway.

A surprising source of methane

Methane emissions from Arctic wetlands, permafrost, and geological seeps are well known. However, until now, the role of glacial meltwater in mobilising methane had been largely overlooked.

Gabrielle and Leonard focused on Vallåkrabreen, a small valley glacier in central Svalbard, where they measured methane levels in groundwater springs and the melt river draining from the glacier.

Their results were striking. Methane concentrations in the melt river were found to be up to 800 times higher than the atmospheric equilibrium level, with peak levels of 3,170 nanomolar recorded early in the melt season.

This methane was not produced by microbial activity beneath the ice, as previously suspected in other glacial settings, but instead came from thermogenic sources—methane that has been trapped in the region’s ancient geological formations for millions of years.

Gabrielle explains:

“We expected to see some methane in the meltwater, but the concentrations we measured were surprisingly high. Our isotopic analysis showed that this methane is geologic in origin and is released as the glacier retreats and glacial meltwater flushes through fractures in the rock.”.

Glacial fracking

By tracking methane concentrations throughout the melt season, the researchers estimated that Vallåkrabreen’s melt river alone released around 616 kg of methane into the atmosphere between June and October.

This accounted for 63% of the total methane emissions from the glacier catchment, with groundwater springs and bubbling gas vents contributing the rest.

Leonard highlights the importance of meltwater in driving these emissions:

“Glaciers act like giant lids, trapping methane underground. But as they melt, water percolates flushes through cracks in the bedrock, carrying transporting the gas to the surface. You can think of as a natural ‘fracking’ process process, or as we have called it: ‘glacial fracking’.”

The study suggests that similar emissions could be happening at hundreds of other glaciers across Svalbard. There are over 1,400 land-terminating glaciers on the archipelago, many of which overlie methane-rich bedrock.

If similar processes are occurring elsewhere, glacial methane emissions could be a substantial and previously unaccounted-for source of Arctic greenhouse gas emissions.

A new climate feedback loop?

The implications of this research go far beyond Svalbard.

The Arctic is warming at four times the global average, and glaciers across the region are shrinking rapidly. As they melt, more methane could be released, creating a positive feedback loop—where warming melts glaciers, releasing methane, which in turn traps more heat in the atmosphere and accelerates further melting.

Gabrielle warns that this process could have global climate consequences:

“Methane is a much more powerful greenhouse gas than carbon dioxide over short timescales. Even though these emissions are seasonal, they could add up as more glaciers retreat.”

Future research agenda

The discovery raises questions about how the Arctic carbon cycle is changing in response to climate change.

Scientists now need to reassess methane budgets in the region, incorporating glacial emissions alongside permafrost thaw and wetland methane fluxes.

This study is the first to document methane emissions from a glacial melt river in Svalbard, but more research is needed to understand the full scale of the problem. The iC3 researchers plan to expand their work to other glacier systems and develop methods to quantify methane emissions on a larger scale.

Find out more

The study, Proglacial methane emissions driven by meltwater and groundwater flushing in a high-Arctic glacial catchment has been published open access in Biogeosciences.

Gabrielle Kleber is a postdoctoral researcher at iC3 and with the Arctic Geology department at the University Centre in Svalbard (UNIS). Her research focuses on Arctic methane emissions and glacial hydrology. Publications here.

Leonard Magerl is a doctoral researcher at iC3, specialising in biogeochemical processes in polar environments. His work investigates the interactions between glaciers, nutrients, and carbon cycling in the Arctic. Publications here.

For more updates on polar research and postdoctoral opportunities at iC3, subscribe to email updates and check out our news page.

Journal

Biogeosciences

DOI

10.5194/bg-22-659-2025

Subject of Research

Not applicable

Article Title

Proglacial methane emissions driven by meltwater and groundwater flushing in a high-Arctic glacial catchment

Article Publication Date

16-Feb-2025

Gabrielle Kleber assesses meltwater streams.

The melt river flows from the terminus of Vallåkrabreen into the valley, where it meets many methane-rich groundwater springs.

Credit

Leonard Magerl / iC3 / UiT

Resilient algae may speed up Greenland ice melt

New research reveals that ice algae can store nutrients which may enable them to colonize more of the ice sheet, darkening and melting it.

Aarhus University

Sampling algae — image:
The dark patches on the Greenland Ice Sheet are algae that bloom during the spring when the snow on of the ice melts. Near the bottom of the picture, you can see researcher Laura Halbach taking samples of the algae for further study.
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Credit: Laura Halbach

It’s May. The sun is up and the heat from that distant star can finally be felt as a warm tingling sensation on the skin.

The snow starts to melt. Flowers and plants break through the ice gasping for light. And the algae living on the ice sheet blooms, darkening the ice.

It’s been like that for thousands of years.

But soon this may change. Spring comes earlier and earlier each year because of climate change and this could enable the algae to colonize larger and larger areas of the ice.

The algae contains brown pigment which darkens the ice. This, in turn, makes the ice melt faster, as its ability to reflect the sun diminishes when it’s darkened.

This has been known by polar researchers for quite some time. But it was believed that the algae has limited capabilities of colonizing the ice, because of the lack of nutrients in this ice desert.

Until now.

New results published in Nature Communications show the algae are able to live off very few nutrients. And that they are able to store and save up energy. This makes it possible for them to colonize much more of the ice sheet than previously thought.

Laura Halbach, who recently got her ph.d.-degree at the Department of Environmental Science at Aarhus University, together with her research team is behind the discovery. Now a postdoc at the Max Planck Institute in Bremen, she continues unravelling the mysteries of the arctic ecosystems.

- My main goal with the trip to Greenland was to understand the mechanisms of the algae bloom formations. With new methods I was able to, as the first researcher ever, to measure the activity of single algae cells from the Greenland Ice Sheet. This led to the discovery of their ability to live off very few nutrients and to store up energy, she says.

The life of an ice alga

Ice algae are small single celled organisms. Elongated, brownish and ellipse shaped.

They thrive on ice surfaces around the world. They have been found on the Greenland ice sheet, in the Alps as well as on glaciers in the Himalayas and Alaska.

Like plants the ice algae releases oxygen through photosynthesis and produces organic molecules. It needs sunlight, water and CO2 as well as small amounts of phosphorus, nitrogen and carbon to survive.

During spring and summer the ice algae blooms creating large patches of darkened ice.

The ice sheet is teeming with life

Not that many years ago the Greenland ice sheet was thought of as a frozen desert. Desolate and almost devoid of life. But since the first researchers from Aarhus University and GFZ Helmholtz Center for Geosciences in Germany arrived in 2020, this has gradually changed.

Now we know that the ice is teeming with microbial life.

Expedition after expedition has revealed more and more of the secret life of the ice algae. One major breakthrough was the discovery that the algae is not alone. A whole ecosystem of microorganisms live on the ice: Bacteria, fungi and even viruses.

But this made it hard to do specific studies of the algae. When researchers scrape off samples of blackened ice, the petri dishes are filled with whole ecosystems. Until now the researchers have only been able to manipulate and test hypotheses on all of the microorganisms at once. And that was what Laura Halbach set out to change.

- If you melt a piece of the surface ice, you see these dark pigmented algae. But there are many organisms in the sample as well as snow-algae, other eukaryotic algae, bacteria and fungi.

- What is commonly done is to incubate the whole community. You give them a nutrient and measure the uptake in the whole community. But then it remains unclear what role the different organisms play.

Zooming in on single cells

Because Laura Halbach was interested in understanding the role of the ice algae in the ecosystem on the ice, she couldn’t just isolate them. Instead, she fed the whole ecosystem marked nutrients. Minuscule isotopic traces that can be recognized by a machine called a mass spectrometer.

- You could say that we kind of labeled the food we gave them. This enabled us to see who ate what. Combined with a machine called SIMS, which is extremely precise, we were able to measure the nutrient uptake of single cells, Laura Halbach explains.

The data from the machine showed that the algae effectively consumed the small amounts of nutrients available – and that they had some stored as well. Something that was completely unknown to the researchers.

- They are very efficient in taking up the limited nutrients on the ice. Furthermore we discovered that they have the capability of storing phosphorus, which is crucial for their metabolism.

Phosphorus is very limited on the ice. Some research suggests that it comes from local rocks containing minerals with phosphorus in them. When the rocks are turned into mineral dust by erosion, it’s scattered across the ice and becomes available to the algae.

A game changer in understanding ice algae

Because the ice algae are able to store phosphorus, they can potentially colonize areas of the ice with very limited amounts of these nutrients. Thus the darkening of the ice might spread to larger areas than was previously thought possible.

- New ice is being exposed on Greenland every year, because the snow melts earlier and earlier. There used to be a thick snow cover all year round, but now large new areas of ice are being exposed to the sun.

- This opens up these areas for the algae to colonize and as they can live on very limited amounts of nutrients it might happen sooner than later.

Laura Halbach's discoveries are not only fascinating but also important, because the knowledge on the algae’s nutrient requirements can help us to better predict their future role in the melting of the Greenland Ice Sheet. Today microbes are not yet integrated into most Earth climate models.

These new discoveries will hopefully be included in the climate models, making them more precise in predicting the melting of the ice in the years to come – and how it will impact the global climate.