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Beneath the Ice in Antarctica

From Pole to Pole, Underwater Robots Help Predict How and When Ice Shelves Collapse

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ice glider, Antarctica
The underwater glider Storm Petrel makes its maiden voyage in Antarctica. (Photo: Damien Guihen/University of Tasmania)

Update Aug. 14:

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To outer space and the deep ocean, add “beneath the ice” to the list of rarely charted frontiers of science exploration.

There have been very few expeditions where robots dived beneath polar ice shelves to characterize and measure them. ϲϿ Davis recently returned from one of them.

Scientist with ice glider
ϲϿ Davis engineering professor Alex Forrest with the recovered underwater glider after its seven-day mission diving in Terra Nova Bay, Antarctica. (Photo: Damien Guihen/University of Tasmania)

Forrest led a six-member robotics team in Antarctica on the Western Ross Sea and Terra Nova Bay as part of an international expedition, LIONESS, led by the Korea Polar Research Institute. That stands for Land-Ice/Ocean Network Exploration with Semiautonomous Systems.

The team spent nearly two months in January and February aboard the South Korean icebreaker R/V Araon.

ice breaker in Antarctica
The R/V Araon, a South Korean icebreaker, moves through ice and ocean just offshore Jang Bogo Station in Antarctica. This shot was captured with an unmanned aerial vehicle. (Photo: Damien Guihen/University of Tasmania)

Their mission? Deploy two robots, or autonomous underwater vehicles (AUV) —  one to dive beneath the sea ice to map the bottom of the Nansen ice shelf, from which . The other, a glider with wings named Storm Petrel, to patrol the front of the ice shelf for 10 days, looking for evidence of freshwater and capturing change over time.

A researcher launches the ice glider from the boat into the antarctic waters.

 

Why? Ultimately, to better predict how — and when — ice shelves collapse.

Antarctica iceberg
An iceberg off the inlet of Jang Bogo Station in Terra Nova Bay, Antarctica. (Photo: Damien Guihen/University of Tasmania)

“Ice shelves are melting,” Forrest said. “We know this. But we don’t know how fast they’re melting. To actually make on-site measurements is the next step. We’re trying to get a baseline understanding of what changes are happening in the Antarctic. As a global community, we don’t really understand what we’re losing.”

From one pole to the other

This July, the team will head in the opposite direction, to the Arctic’s Milne Fjord, where Forrest and colleagues plan to study the last epishelf lake in Canada.

Epishelf lakes form when meltwater flowing off a glacier is trapped behind a floating ice shelf. As ice shelves in the Arctic disappear, so do the epishelf lakes dammed behind them. While Canada may soon be epishelf-free, others remain in Greenland and Antarctica. The research is intended to better explain time scales, as ice shelves are melting faster than scientists earlier predicted.

Aerial Antarctica
A teal ribbon of water flows on top of a glacier at Inaccessible Island, an extinct volcano and protected wildlife reserve in the South Atlantic Ocean. An uncommon sight, the researchers were unsure whether the ocean was rising over the ice, or whether freshwater was melting and flowing downward in this shot. The small black dots to the right of the teal green water are seals basking in the sun. (Photo: Damien Guihen/University of Tasmania)

“It comes down to understanding how this environment is now so we can understand how potential future climate scenarios will drive these systems in Greenland and Antarctica, as well,” Forrest said.

scientists on boat, Antarctica
Fishing for a glider: Damien Guihen with the University of Tasmania and Xian Wei Wang, from New York University in Abu Dhabi, retrieve the autonomous underwater vehicle. (Credit Cassie Bongiovanni/University of New Hampshire)

Ice glider to deploy at Lake Tahoe

When not swimming alongside polar ice, the Storm Petrel glider trades the ocean for freshwater. It’s currently settling in to its new home at Lake Tahoe, which stretches across the California and Nevada borders. The plans to deploy it in the lake early this summer.

The plan is for the glider to take continuous measurements, provide real-time information to TERC’s network of instrumented buoys, chase storm events, and ultimately help round out the picture of the processes and impacts affecting Lake Tahoe.

“Lakes are highly variable, both spatially and in time,” said Geoffrey Schladow, director of the ϲϿ Davis Tahoe Environmental Research Center. “Conventional measurements cannot capture this dynamism. But with a glider operating for weeks at a time, from the surface to the very bottom, we finally have the appropriate tool.” 

Adelie penguins in Antarctica
Adélie penguins live only in Antarctica. They are seen here with a seal in the background. Alex Forrest was amazed by Antarctica’s wildlife. He said that, unlike in the Arctic, wildlife in Antarctica have few predators, so they had little fear of humans. (Photo: Danielle Haulsee, University of Delaware)

Lake Tahoe is getting “smarter” all the time with its network of nearshore sensors, NASA buoys and good old-fashioned manual sampling from TERC’s research vessel. But the glider can do something those other tools cannot: Move around the lake in bad weather and rough conditions.

And, as nearly everyone who studies freshwater lakes can attest, bad weather — with its mixing, churning, swelling and upwelling — is when everything really interesting happens in a lake.  

Be it at the poles, or in a California lake, the data these robots collect are helping to shape the picture of how aquatic environments are changing, and what might be expected in the years to come.

Ice on water in Antarctica
View from the research vessel across sea ice at Terra Nova Bay. While the scene appears serene -- and much of Antarctica is utterly silent – it was actually noisy here. Ice chunks float atop the water, making quite a ruckus when they crash against each other. Seals popping their heads up to call to each other and swooping sea birds add to the cacophony of Antarctica at sea. (Photo: Damien Guihen/University of Tasmania)

 

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Kat Kerlin, 530-750-9195, kekerlin@ucdavis.edu

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