Tackling Mount Rainier's Deadly Ice Caves for Science

This team crossed invisible lakes of noxious gas to map the mountain's mysterious caves and search for clues to life on Mars.

By Andrew Bisharat
Published 6 Oct 2018, 17:20 BST

How far would you go in the name of science and exploration? A team of cavers and researchers studying Mount Rainier’s curious network of glacier ice caves found out their answer after a permit rejection from the National Park Service.

The group had requested permission to use a helicopter to shuttle 1,700 kilogrammes (1,800 pounds) of scientific, safety, medical, and expedition equipment to a camp at almost 5,000 metres (14,250 feet). They needed the gear, which included a NASA ice-climbing robot that may one day explore Martian ice caps, to land at a volcanic crater just beneath Rainier’s summit. The whole load could’ve been transported during a single trip in an external sling, according to Eddy Cartaya, a lead organiser of the Mount Rainier Fumarole Cave Expedition.

Yet, to the frustration of Cartaya and his team, the Park Service denied their helicopter request.

Undeterred by 21st-century bureaucracy, Cartaya turned to old-fashioned 19th-century mountaineering tactics to get their gear to the top of the mountain.

Expedition doctor Woody Peebles explores a previously unknown portion of a Mount Rainier cave.
Photograph by Francois Xavier DeRuydts, National Geographic

In late July 2017, over 100 people—mountain rescuers, cavers from the National Speleological Society, and other locals—volunteered themselves to porter the equipment from the parking lot to the summit of the Cascades’ preeminent peak.

“I think it was probably the biggest caving expedition in North America,” says Cartaya. “Possibly the biggest in history.”

“I think it is certainly one of the largest in recent years,” says Gary Schindel, president of the National Speleological Society. “The Mount Rainier [expedition] may be the most difficult and audacious but not sure if it was the largest.”

Adventure Atop a Volcano

Mount Rainier dominates the region’s landscape. It has a topographic prominence—the height it rises relative to the surrounding topography—of 4,400-metre (13,210 feet), which is greater than that of K2. Ascending its heavily glaciated slopes takes most climbers two to three days, and by the time they reach the summit, they’re typically wrecked from the exertion and altitude.

“It’s all most climbers can do to snap a photo and run the hell down. No one in their right mind really would ever want to go up there and spend 10 days,” says Cartaya.

For Cartaya and his team, Rainier’s summit is the starting point for the real adventure. Deep within the glacier plugging the summit crater are the fumarole caves, a network of tunnels and chambers 2.2 miles long and 150 metres (465 feet) deep, carved into the ice cap by the slow release of fumarolic steam and gases from the belly of the mountain.

Eddy Cartaya climbs down an ice wall with the help of James Frystak, placing ablation markers to measure the melting ice over time.
Photograph by Francois Xavier DeRuydts, National Geographic

“It's terrible to be up there for so long,” says Cartaya. “You're always cold. You're always tired. You always feel sick. You’re exhausted. It really sucks. But everyone's excited because they're so passionate about doing this work and sharing it together as a team. It's this bizarre kind of elation, I guess, to be part of something like that.”

First explored by Seattle-based caver Bill Lokey in the early 1970s, Rainier’s fumarole caves haven’t been meaningfully surveyed or studied until now.

The goals of this multi-year expedition, slated to wrap in 2020, are to complete a three-dimensional survey of two cave systems in the ice cap and conduct geo-microbiology, geochemistry, and climatology studies.

Entering the caves, however, carries its own unique and extreme risks.

Invisible Killer Lakes

Invisible and odourless 'lakes' of relatively heavier carbon-dioxide gas, released by the fumaroles, form at the bottom of pits and dead-end tunnels. These CO2 lakes represent one of the caves’ gravest dangers, forcing expedition members to carry CO2 monitors and re-breathers that would provide the 20 minutes of air needed to escape.

Already, the team has experienced close calls. During the 2017 trip, Christian Stenner, a Canadian caver, slipped and fell down a steep passage in one of the bore holes near the summit of Rainier. Giant boulders tumbled alongside him as he fell.

He came to a stop where the passage dead-ended and was fortunately unhurt. He was having trouble breathing, which he initially attributed to being shaken by the fall, but soon realised he was in a CO2 trap.

“I had a feeling of panic and a moment of impending doom,” says Stenner. “I knew I wasn’t getting enough air, and I felt like I was going to drop.”

Stenner hastily clawed his way back up to his teammate, where he composed himself, and ultimately the two managed to escape the cave before passing out.

In another incident, Cartaya himself experienced the surreal 'chemical suffocation' of being in a CO2 trap. He says, “I remember feeling a sense of impending doom, just like someone's got a bag over your head. It's very scary feeling.”

Scientists Andreas Pflitsch and David Holmgren work to place a probe that measures temperature and depth at the bottom of Lake Adelie.
Photograph by Francois Xavier DeRuydts, National Geographic

The Science Goes On

The Mount Rainier Fumarole Cave Expedition team has more than one goal. The geographical surveys will help in both mapping and future search and rescue efforts, as climbers have been known to duck into the caves to wait out bad weather. The scientific studies will help researchers understand the complex formation processes of the caves and model the ablation of the glacier.

There’s also an effort by Dr. Penny Boston, the director at NASA’s Astrobiology Institute, to study the geo-microbiology of the caves. Tiny, rare organisms broadly classified as 'extremophiles' are living in these incredibly harsh environments, feeding off of the noxious gases released by the fumaroles. These environments could serve as models for life in places like Mars. An ice-climbing robot designed to collect these samples is being tested for deployment on Mars.

“It’s a huge source of satisfaction that we're furthering science and facilitating these academic discoveries to make a holistic representation of the cave,” says Cartaya.

Next year, Cartaya and his team are hoping to bring up a number of anemometers, expensive and extremely fragile devices that measure air flow, temperature, and other data. The thought of carrying these delicate apparatuses causes Cartaya to shake his head.

“Hopefully, we can get a helicopter next year,” he says.

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