The Yellowstone supervolcano is a disaster waiting to happen
A caldera-forming volcano supplies the heat for the hydrothermal features in Yellowstone National Park. (Jonathan Newton/The Washington Post)
Yellowstone National Park sits squarely over a giant, active volcano. This requires attention.
Yellowstone
has been a national park since 1872, but it was only in the 1960s that
scientists realized the scale of the volcano — it's 44 miles across —
and not until the 1980s did they grasp that this thing is fully alive
and still threatens to erupt catastrophically.
Yellowstone
is capable of eruptions thousands of times more violent than the Mount
St. Helens eruption of 1980. The northern Rockies would be buried in multiple feet of ash.
Ash would rain on almost everyone in the United States. It'd be a bad
day. Thus geologists are eager to understand what, exactly, is happening
below all those volcano-fueled hot springs and geysers.
Obviously
they would like to know if and when Yellowstone will blow again, and
with what level of explosiveness. A major eruption would be a
low-probability, high-consequence event, a proverbial Black Swan,
something that could have societal and planetary effects. The problem
for scientists is that these big “supervolcano” eruptions rarely happen,
and the most important action is out of sight, many miles below the
surface, involving chaotic forces, complex chemistry and enigmatic
geological features.
One
new study has offered insight on Yellowstone’s hidden architecture.
It modeled the way magma rises from deep in Earth’s interior and creates
two large chambers of partially melted rock beneath the surface of the
national park.
These two magma chambers are
stacked, and they are separated by a layer (called a “sill,” like a
window sill) of non-melted rock. The magma rising from Earth's mantle
flows easily and doesn't hold much gas. It cools and solidifies as it
collides with relatively cold crust, forming the sill, the top of which
is about six miles below the surface.
On top of
the sill is the upper magma chamber, with thick, sticky magma that holds
a great deal of gas — which makes the magma in the upper chamber
explosive. It's like an unopened can of soda that has been shaken. Open
the can at your peril.
The new study, published in Geophysical Research Letters, explains how this two-tiered, geochemically diverse architecture might have come about over the course of time.
“Someday
we might have a model snapshot saying this is what the system looks
like when there’s enough melt for there to be a large eruption,” lead
author Dylan Colón, an earth sciences doctoral candidate at the
University of Oregon, told The Washington Post.
The study won praise from Michael Poland, scientist-in-charge at the U.S. Geological Survey's Yellowstone Volcano Observatory:
“What's neat about their model is they can go back in time with it and
see how it might have influenced eruption rates many millions of years
ago.”
The new study bolsters earlier research on the dual magma chambers. It
used sensors arrayed around Yellowstone to record the speed at which
seismic waves from small earthquakes pass through the subsurface rock.
Such waves move more slowly through hot and/or partially melted rock
formations. That data gave scientists the equivalent of an MRI showing
the two magma chambers.
A 2015 study revealed a gigantic magma reservoir beneath the previously known Yellowstone magma chamber. This cross-section illustration cutting southwest-northeast under Yellowstone depicts the view revealed by seismic imaging. (Hsin-Hua Huang/University of Utah)
“Supervolcano,”
we should note, is not a technical term. The experts refer to
Yellowstone as a “caldera” or a “caldera-forming volcano.” Some
volcanoes form conical mountains. A caldera is a volcano that creates a
vast crater. These are mountain-swallowing events. Visitors to
Yellowstone are given a map showing the outline of the most recent
caldera, and if they go to the right vantage point, it's possible to see
that the heart of the park is remarkably free of mountains. They were
either blown away or fell into the big hole.
The
Yellowstone region has seen three big eruptions, the first one 2.1
million years ago, the most recent 630,000 years ago. Contrary to
Internet rumor-mongering, as well as conspiracy theories about
government coverups, there's no sign that a fourth cataclysmic event is
about to happen.
It's possible, in fact, that
Yellowstone is getting a bit old and tired. It may be ready for a long
nap rather than a major eruption.
Ilya
Bindeman, a University of Oregon geochemist and co-author of the new
paper, said that Yellowstone may be “approaching the end of its
evolution” because so much of the material in the upper magma chamber is
recycled and re-melted after previous eruptions.
As
Poland said: “How many times do you want to reheat your leftovers? At
some point you’re going to say, 'I’m not going to reheat this.' You’ve
microwaved it six times, and it's no longer food.”
Intellectual
humility is called for here: No one can say with great confidence how
much magma it takes to trigger a caldera-forming eruption. Moreover,
relatively small eruptions creating lava flows can happen within the
Yellowstone system. The most recent was 70,000 years ago. The experts
say one of these smaller eruptions is much more likely than a giant
explosion. Speculation that Yellowstone is “due” to erupt
catastrophically implies that the volcano behaves predictably, like a
machine. Geologists know otherwise.
Yellowstone, it should be noted,
isn't the only caldera in the United States. One of the others that's
worth keeping an eye on — and the U.S. Geological Survey does just that —
is the Long Valley caldera in California, near the popular ski resort
of Mammoth Mountain, just east of Yosemite National Park. It erupted
700,000 years ago. A major eruption is extremely unlikely, but it could
produce smaller eruptions that would be highly disruptive and dangerous,
said Margaret Mangan, scientist-in-charge at the USGS California
Volcano Observatory.
Mangan said there are
seven volcanic regions in California with zones of molten rock beneath
the surface. A volcanic eruption in California is roughly as likely as a
magnitude 6 or greater earthquake on the San Andreas Fault, she said.
But
Californians don't worry about volcanoes. They worry about earthquakes,
tsunamis and wildfires, she said. She has tried to raise public
awareness of volcano hazards but says that it is hard to get much
attention.
“The awareness level and
preparedness level is quite low in this state,” she said. “We prepare
for those large earthquake events, and we need to prepare for volcanic
eruptions.”
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