We are truly learning how to map the subsurface geology and this will become seriously helpful. In time every part of our active volcanic zones can be so mapped. There are likely not many failed volcanoes out there but we certainly want to understand the real capabilties of every active volcano out there.
One
reason I bring this up is that we have been consistently surprised.
We really do need to understand when a Thera is possible or a
Vesuvius or even Mt St Helens which easily killed a bunch of folks
because we did not umnderstand side collapse. Worse when the
mountain was lifting a foot per day or worse, folks actually hung
around to watch a nuclear bomb reach trigger point.
Bad
decissions can be easily made and underestimating a volcano is one of
them.
Cracking the
Secrets of Deadly Volcanic Eruptions
Becky Oskin, Senior
Write
July 16, 2014 01:00pm
ET
Molten rock travels a
long road before it spews from volcanoes during deadly eruptions.
Mapping out the journey could help scientists better understand how
volcanoes work and improve early warnings of oncoming blasts, but
tracking down blobs of magma deep within the Earth's crust is no easy
task./
Now, at Washington's
Mount Rainier and Mount St. Helens, two of the most
dangerous volcanoes in the United States, researchers are
getting their best look yet at magma's underground path via a pair of
new scientific studies.
The first study,
published today (July 16) in the journal Nature, clearly illustrates
how magma is produced deep beneath Mount Rainier. With the second
study, which is just getting underway, researchers hope to generate
similarly revealing results for Mount St. Helens.
Birth of the Cascades
Mount Rainier
and Mount St. Helens are two of scores of snow-capped
volcanoes that march up the West Coast, from Northern California to
British Columbia, Canada. If Mount Rainier erupts, its glaciers could
melt and trigger lethal mudflows called lahars that would race
through the Seattle-Tacoma metropolitan area. Similar lahars scoured
the landscape when Mount St. Helens erupted in 1980.
The Cascade volcanoes
belch and smoke because of a collision between two tectonic plates —
the pieces of crust that shift and slide on Earth's surface. One
plate, the Juan de Fuca, is sliding eastward and descending below the
westward-moving North American Plate. This collision between the two
plates is called a subduction zone.
Subduction zones birth
volcanoes because the sinking crust is wet — it's been soaking at
the bottom of the ocean for millions of years. As the Juan de Fuca
plate inches downward, the temperature and pressure on the plate
rises, altering the rocks in the subducting crust. Water
locked in minerals in the rocks escapes as the heat and pressure
increase, and the water slowly rises toward the surface. Adding a
little water to the rocks above the subduction zone lowers their
melting point, creating magma.
Magnetic magma
In 2006, researchers
measured variations in magnetic and electrical fields beneath Mount
Rainier to see how this process of subduction feeds magma to
Washington's volcanoes, Magnetic and electric conductivity fluctuates
with changes in geologic structures underground, and water and molten
rocks show up especially clearly with this method, said lead study
author Shane McGary, a geophysicist at the College of New Jersey in
Ewing. A seismic study done at the same time as the magentotelluric
survey helped the researchers resolve the boundaries between solid
and molten rock.
The results clearly
illuminate the route molten rocks take from their underground
birthplace in the subduction zone, to the magma chamber
beneath Mount Rainer.
"The most
striking thing is we can clearly see the slab to surface path,"
McGary said of the results.
Here's how Mount
Rainer's magma forms, according to the study. Water escapes from the
top of the Juan de Fuca plate about 50 miles (80 kilometers) below
the volcano. The fluids come up and trigger melting in the overlying
rock, and this mix of water and magma rises like an
elevator straight toward the surface. (Water squeezed out at
shallower depths of 25 miles (40 km) also travels over and joins this
ascending mix.)
For unknown reasons,
the elevator shaft is on the coastal side of Mount Rainier,
not directly underneath the volcano. Within 12 miles (20
km) of the Earth's surface, the magma slush shifts eastward toward
Mount Rainier.
"I don't think
anyone knows why volcanoes don't form directly above [the rising
magma], but this seems to be the characteristic of subduction zones,"
McGary said.
Looking deep
Soon, however,
scientists may solve the puzzle of what's happening with the shifting
magma.
This summer, a horde
of volunteers is helping researchers set off small explosions all
over Mount St. Helens to peer into the volcano's depth. The
explosions are much smaller than the earthquakes that rock the
volcano daily, and present no risk of setting off an eruption,
according to the project scientists.
The energy from the
explosions will be recorded on thousands of portable seismometers, or
earthquake monitors, placed by volunteers. The experiment will
provide the clearest picture yet of the geology beneath Mount St.
Helens. The explosions are part of a $3 million, multiyear project
called iMUSH, for Imaging Magma Under St. Helens.
"We conceived of
the study because we have a decent idea of what's happening in the
upper crust [underneath Mount St. Helens], but we've had trouble
looking deeper," said John Vidale, director of the University of
Washington-based Pacific Northwest Seismic Network, and one of the
leaders of the project. "This will tell us where the pathways of
the magma are, and the geologic structures through which they're
moving."
In addition to the
temporary seismometers, scientists will expand the permanent seismic
listening network at the volcano and conduct a magnetic and
electrical survey even larger than the Mount Rainier experiment.
The overall goal is to
probe Mount St. Helens' depths and see how the volcano connects to
its neighbors. For instance, does its magma pool in a giant
underground reservoir that connects to Mount Rainier and Mount Adams?
Or does each volcano have its own supply? And does the molten rock
rise in fits and starts, or is there a speedy route to the surface?
"We know there's
magma underneath these volcanoes, but if we can image the source and
understand the relationship between them, it could tell us important
things about this area," said Adam Schultz, a geophysicist at
Oregon State University in Corvallis, who is also helping lead the
project.
The answers will also
help researchers understand how volcanoes fill their tanks after
eruptions.
Earlier this year, the
U.S. Geological Survey announced that Mount St. Helens was
showing signs of slowly filling again with magma.
Email Becky
Oskin or follow her @beckyoskin. Follow
us @livescience,Facebook & Google+. Original
article on Live Science.
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