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Around 1860, a naturalist on a railroad
survey noted many dead trunks of Western
Redcedar standing along the shores of
Willapa Bay on the southern Washington
coast. More than a hundred years later, in
the late 1980’s, scientists discovered what
killed the trees. Their roots had been
submerged in saltwater when forested land
dropped below sea level during a great
earthquake (magnitude 8 or more) about 300
years ago. With that discovery came the
realization that a great earthquake could
strike the region again.
Pacific Northwest Quakes
The Pacific Northwest sits atop the Casca-
dia subduction zone, where two great slabs
of the Earth’s crust—called tectonic plates—
are converging. The Juan de Fuca plate on
the west, made up of dense oceanic crust, is
shoving eastward beneath the North Ameri-
can plate, made of lighter, continental crust.
The grinding of plates past each other in
subduction zones sometimes generates deep
earthquakes—originating tens of kilometers
beneath the earth’s surface. Subduction-zone
earthquakes can be huge; the magnitude 9.2
earthquake that struck Alaska in 1964 is an
example. Until recently, scientists consid-
ered the Cascadia subduction zone to be
moving smoothly and unlikely to generate
big earthquakes. But by the late 1980’s, evi-
dence such as drowned forests, tsunami
deposits, and sediments liquefied by shaking
showed that the Cascadia subduction zone
had produced great earthquakes in the past
and could do so again. Added to that was
evidence in the Puget Sound area for past
large earthquakes generated on faults near
the surface, such as the Seattle fault (see
map and figure on back page). These discov-
eries inspired the U.S. Geological Survey
(USGS) and other institutions to study the
Pacific Northwest more intently, to assist
decision makers in assessing and mitigating
earthquake hazards there.
Experiments in Puget Sound
Earth scientists from the USGS and eight
cooperating institutions (see list on back
page) are currently conducting a study called
SHIPS, or Seismic Hazards Investigation in
Puget Sound.
Though scientists cannot yet predict
when earthquakes will strike, they can deter-
mine where earthquakes will strike and
where the shaking will be most violent. To
this end, SHIPS scientists are using sound
waves to build up images of the sediment
Scientists Use Sound Waves to Probe
Earthquake Hazards in the Puget Sound Area
U.S. Department of the Interior
U.S. Geological Survey
USGS information sheet
August 1999
“Geological evidence for past great earthquakes is clear, but basic information about regional earthquake processes is lacking. Knowing more
about the structures underlying the region should give a clearer picture of the places most susceptible to violent shaking, landslides, and
structural damage during earthquakes. City planners will have a rational basis for allocating scarce resources for such things as
strengthening bridges, schools, and hospitals.”—Michael A. Fisher, U.S. Geological Survey
E
merging evidence shows that
damaging earthquakes of
magnitude 8 or greater could strike the
Pacific Northwest, a region that
stretches from northern California
through Oregon and Washington into
British Columbia, Canada. This region
includes large population centers such
as Portland, Seattle, and Vancouver,
Canada. To study the earthquake threat
in and around Seattle, the U.S.
Geological Survey (USGS) and eight
cooperating institutions launched
SHIPS—Seismic Hazards Investigation
in Puget Sound. SHIPS scientists are
using sound waves to probe sediment
and rock layers beneath the Puget
Sound area. The faults and other
features they uncover will help them
determine where the worst earthquake
damage is likely to occur.
University of Washington’s Research Vessel Thomas G. Thompson towed an array of airguns (to left
of photo) through Puget Sound beside downtown Seattle in March 1998. Bursts of sound from the
airguns bounced off rock layers deep beneath the earth’s surface. Returning echoes built up a picture
of the rock layers and faults that cut them. These data will be combined with on-land SHIPS data
collected in September 1999 to create a complete three-dimensional view of the sediment and rock
layers beneath the Seattle area. (Photograph by David L. Carver, U.S. Geological Survey)
