Verb as Complement
Nepal
earthquake offers hints of worse to come
On April 25, a major earthquake devastated Nepal. The shaking
collapsed buildings, triggered avalanches and killed at least 5,000 people.
Unfortunately, the magnitude-7.8 quake won’t be the last to hit
this region of southern Asia. Even larger quakes could strike to the west,
scientists warn. The same goes for east of Nepal, in nearby Bhutan.
Earthquakes happen along fractures in Earth’s crust, called
faults. Some faults mark the boundaries between giant slabs, called tectonic
plates. These plates make up Earth’s uppermost layer. Nepal sits atop the
boundary between the Indian and Eurasian plates.
The coming together of these two plates also uplifts the Himalayan
mountain range. This range’s soaring peaks include the world’s tallest
mountain, Mount Everest. But as plates slide and push against each other, some
stress will develop. And it keeps building until parts of Earth’s crust slide
or slip. This triggers a quake.
The recent Nepal earthquake relieved some stress along just one
stretch of that fault. In time, other segments along that boundary between the
plates could produce even larger quakes, scientists warn.
The size and location of future quakes in the region will depend
in part on the shape of the fault responsible for the Nepal quake. Right now,
researchers don’t fully understand that shape. However, new research has
provided some glimpses. And it suggests that some areas could be even more at
risk of strong quakes than previously thought.
“The hazard isn’t gone,” says Kristin Morell. She’s a geologist of
the University of Victoria in Canada. “The Himalayas are a very long mountain
belt,” she notes. “And strain is still building up in all the other regions
from Pakistan all the way to eastern Tibet.”
Slipping slowly, until wham!
For around 50 million years, the Indian tectonic plate has been
slipping under the Eurasian Plate. The Indian plate slips at a rate of about 15
to 20 millimeters (0.6 to 0.8 inch) each year. This slow slide doesn’t always
go smoothly. The Indian plate dives downward at different angles along various
parts of the boundary between the plates. In some places, the plate is almost
level. At others, it plunges at an angle of more than 30 degrees.
Steeper angles increase friction between the
plates. And with friction, stress builds up. The energy can accumulate over
centuries — only to be released in seconds during an earthquake. The spot where
the Nepal quake began, called its epicenter, was along one of these
strongly sloping sections.
When an earthquake hits, it doesn’t strike along the full stretch
of a fault. Scientists believe this is because of physical barriers along the
fault that can halt the movement. These barriers can include locations where
the angle between two plates changes quickly. In general, the larger an
uninterrupted fault segment, the more powerful the earthquakes it can produce.
At places, the Himalayan fault hides tens of kilometers (miles)
below ground. Experts know little about large sections of this fault. Luckily
researchers have indirect ways to “eye” the fault’s layout. The buried fault
can cause changes on the surface above. For example, where the Indian plate
dips steeply, it pushes the overlying ground upward. This uplift steepens the terrain. And that
causes erosion. Streams here cut deeply into the ground too.
By looking at the surface, Morell and her colleagues have been
able to make out the structure of part of the fault. This segment lies west of
where the recent earthquake struck. The area includes a spot where the angle
between the plates rapidly steepens. A magnitude 8 or greater quake could
happen on either side of this transition, the researchers reported online March
12 in the journal Lithosphere. (The earthquake scale is not linear,
so a magnitude 8 quake would actually be at least 1.5 times more powerful than
a 7.8 quake.)
A separate research team used a similar technique to look at a
fault farther east. That fault is in the nation of Bhutan. There, the experts
uncovered a wide segment of fault that appears to have no boundaries. That
means this large segment of uninterrupted fault has the potential to produce
even larger earthquakes than previously expected. Details on this fault will
appear in a future issue of Geophysical Research Letters.
“If there is a big earthquake in Bhutan, it could be larger than
the recent earthquake in Nepal,” says coauthor Rodolphe Cattin. He is a
geophysicist at the University of Montpellier in France. (Geophysics is the
study of matter and energy on Earth and how they interact.)
A fault to the west of the Nepal quake’s epicenter could be
prepped for a big quake as well, says Simon Klemperer. He's a
geophysicist at Stanford University in Palo Alto, Calif. In fact, that
fault segment is at least twice as long as the one that recently rattled the
country’s eastern side. This western segment has been building stress since its
last major quake in 1505.
“The earthquake I worry about is not the one that happened” on
April 25, says Klemperer. “It’s the one that could be a magnitude 8.6 to the
west.”
Power Words
angle The space (usually measured in degrees) between two
intersecting lines or surfaces at or close to the point where they meet.
earthquake A sudden and sometimes violent shaking of the
ground, sometimes causing great destruction, as a result of movements within
Earth’s crust or of volcanic action.
crust (in geology) Earth’s outermost surface, usually
made from dense, solid rock.
epicenter The underground location along a fault where an
earthquake starts.
erosion The process that removes rock and soil from one spot on
Earth’s surface and then deposits the material elsewhere. Erosion can be
exceptionally fast or exceedingly slow. Causes of erosion include wind, water
(including rainfall and floods), the scouring action of glaciers, and the
repeated cycles of freezing and thawing that often occur in some areas of the
world.
fault In geology, a fracture along which there is movement of
part of Earth’s rocky, outermost shell, or lithosphere.
fracture (noun) A break. (verb) To break something and
induce cracks or a splitting apart of something.
friction The resistance that one surface or object encounters when
moving over or through another material (such as a fluid or a gas). Friction
generally causes a heating, which can damage the surface of the materials
rubbing against one another.
geology The study of Earth’s physical structure and substance, its
history and the processes that act on it. People who work in this field are
known as geologists. Planetary geology is the science of studying the same
things about other planets.
geophysics The study of matter and energy on Earth and how
they interact.
plate tectonics The study of massive moving pieces that
make up Earth’s outer layer, which is called the lithosphere, and the processes
that cause those rock masses to rise from inside Earth, travel along its
surface, and sink back down.
range The full extent or distribution of something. For instance,
a plant or animal’s range is the area over which it naturally exists. (in math
or for measurements) The extent to which variation in values is possible.
strain (in physics) The forces or stresses that seek to twist or
otherwise deform a rigid or semi-rigid object.
stress (in physics) Pressure or tension exerted on a material object.
tectonic plates The gigantic slabs — some spanning
thousands of kilometers (or miles) across — that make up Earth’s outer layer.
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