It has long been known that the Cascadia subduction zone is able to
deliver a magnitude 9 event having done so three hundred years ago.
What we have lacked is meaningful comparisons for folks living in the
areas of population concentration. So a few thoughts are in order.
A tsunami will happen, but it is almost no threat around the inland
waters of the Salish Sea. On the Pacific side there is plenty of
risk but limited outright exposure except around the Columbia river.
Otherwise the coastal population is modest but all fatally exposed by
and large. I have driven through areas that I thought that they were
crazy to build on.
Thus the real damage will be caused by outright shaking of the
ground. The houses themselves will stand up very well minimizing the
loss of life but otherwise will be mostly wreaked. Recall that a Mag
9 shake will be heavily damped by the coastal mountains on its way to
population centers.
The more serious problem in Vancouver will be land slips on the
housing covered hillsides. Most will not be large but foundations
will be generally destroyed easily were they lack stone bases.
Anther serious risk will be liquid-faction in the Fraser Delta.
Fortunately it is all above sea level. Again we will have wreaked
foundations.
My own sense is that we are two centuries away and that the damage
although severe enough will be readily recovered from at the housing
level while most of the rest will ride through surprisingly well.
It has to also be said that good Earthquake standards have been in
place for thirty years and every serious renovation has been
included. Thus our building stock is likely already mostly up to
standard since this city has been building steadily.
Seattle is also cycling out most of their most vulnerable structures
and give it another generation and it will all be mostly survivable.
Himalayas and Pacific Northwest
could experience major earthquakes, Stanford geophysicists say
by Bjorn Carey for Stanford News
Stanford CA (SPX) Dec 11, 2012
Stanford geophysicists are well
represented at the meeting of the American Geophysical Union this
week in San Francisco. Included among the many presentations will be
several studies that relate to predicting - and preparing for -
major earthquakes in the Himalaya Mountains and the Pacific
Northwest.
The AGU Fall Meeting is the largest
worldwide conference in the geophysical sciences, attracting more
than 20,000 Earth and space scientists, educators, students, and
other leaders. This 45th annual fall meeting is taking place through
Dec. 7 at the Moscone Convention Center in San Francisco.
A big one in the Himalayas
The Himalayan range was formed, and remains currently active, due to the collision of the Indian and Asian continental plates. Scientists have known for some time that India is subducting under Asia, and have recently begun studying the complexity of this volatile collision zone in greater detail, particularly the fault that separates the two plates, the Main Himalayan Thrust (MHT).
Previous observations had indicated
a relatively uniform fault plane that dipped a few degrees to the
north. To produce a clearer picture of the fault, Warren Caldwell, a
geophysics doctoral student at Stanford, has analyzed seismic data
from 20 seismometers deployed for two years across the Himalayas by
colleagues at the National Geophysical Research Institute of India.
The data imaged a thrust dipping a
gentle two to four degrees northward, as has been previously
inferred, but also revealed a segment of the thrust that dips more
steeply (15 degrees downward) for 20 kilometers. Such a ramp has been
postulated to be a nucleation point for massive earthquakes in
the Himalaya.
Although Caldwell emphasized that
his research focuses on imaging the fault, not on predicting
earthquakes, he noted that the MHT has historically been
responsible for a magnitude 8 to 9 earthquake every several
hundred years.
"What we're observing doesn't
bear on where we are in the earthquake cycle, but it has implications
in predicting earthquake magnitude," Caldwell said. "From
our imaging, the ramp location is a bit farther north than has been
previously observed, which would create a larger rupture width and a
larger magnitude earthquake."
Caldwell will present a poster
detailing the research on Tuesday, Dec. 4, from 1:40 p.m. to 6 p.m.
in Moscone South, Halls A-C.
Caldwell's adviser, geophysics
Professor Simon Klemperer, added that recent detections of magma and
water around the MHT indicate which segments of the thrust will
rupture during an earthquake.
"We think that the big
thrust vault will probably rupture southward to the Earth's
surface, but we don't expect significant rupture north of there,"
Klemperer said. The findings are important for creating risk
assessments and disaster plans for the heavily populated cities in
the region.
Klemperer spoke about the evolution
of geophysical studies of the Himalayas (Dec. 3) from 1:40 p.m. to
3:40 p.m. in Moscone South.
Measuring small tremors in the
Pacific Northwest
The Cascadia subduction zone, which stretches from northern California to Vancouver Island, has not experienced a major seismic event since it ruptured in 1700, an 8.7-9.2 magnitude earthquake that shook the region and created a tsunami that reached Japan.
And while many geophysicists believe
the fault is due for a similar scale event, the relative lack of any
earthquake data in the Pacific Northwest makes it difficult to
predict how ground motion from a future event would propagate in the
Cascadia area, which runs through Seattle, Portland and Vancouver.
Stanford postdoctoral scholar
Annemarie Baltay will present research on how measurements of small
seismic tremors in the region can be utilized to determine how ground
motion from larger events might behave.
Baltay's research involves measuring
low amplitude tectonic tremor that occurs 30 kilometers below Earth's
surface, at the intersections of tectonic plates, roughly over the
course of a month each year.
By analyzing how the tremor signal
decays along and away from the Cascadia subduction zone, Baltay can
calculate how ground motion activity from a larger earthquake will
dissipate. An important application of the work will be to help
inform new construction how best to mitigate damage should a large
earthquake strike.
"We can't predict when an
earthquake will occur, but we can try to be very prepared for them,"
Baltay said. "Looking at these episodic tremor events can help
us constrain what the ground motion might be like in a certain place
during an earthquake."
Though Baltay has focused on the
Cascadia subduction zone, she said that the technique could be
applied in areas of high earthquake risk around the world, such as
Alaska and Japan.
Baltay will present a poster
presentation of the research on Wednesday (Dec. 5) from 1:40 p.m. to
5:40 p.m in Moscone South, Halls A-C.
Cascadia quake simulations
The slow slip and tremor events in Cascadia are also being studied by Stanford geophysics Professor Paul Segall, although in an entirely different manner. Segall's group uses computational models of the region to determine whether the cumulative effects of many small events can trigger a major earthquake.
"You have these small events
every 15 months or so, and a magnitude 9 earthquake every 500 years.
We need to known whether you want to raise an alert every time one of
these small events happens," Segall said.
"We're doing sophisticated
numerical calculations to simulate these slow events and see whether
they do relate to big earthquakes over time. What our calculations
have shown is that ultimately these slow events do evolve into
the ultimate fast event, and it does this on a pretty short time
scale."
Unfortunately, so far Segall's group
has not seen any obvious differences in the numerical simulations
between the average slow slip event and those that directly precede a
big earthquake.
The work is still young, and Segall
noted that the model needs refinement to better match actual
observations and to possibly identify the signature of the event that
triggers a large earthquake.
"We're not so confident in our
model that public policy should be based on the output of our
calculations, but we're working in that direction," Segall said.
One thing that makes Segall's work
difficult is a lack of data from actual earthquakes in the Cascadia
region. Earlier this year, however, earthquakes in Mexico and Costa
Rica occurred in areas that experience slow slip events similar to
those in Cascadia.
Segall plans to speak with
geophysicists who have studied the lead-up to those earthquakes to
compare the data to his simulations.
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