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Primary
waves travel around 6 kilometers (4 miles) per second, covering around
60 kilometers
(40 miles) in 10 seconds. Secondary, or S waves, that are usually more
destructive, travel more slowly, around 3.5 kilometers (2.2 miles) per
second,
covering only around 17 kilometers (11 miles) in 10 seconds. Therefore,
a city
located around 60 kilometers (40 miles) from an epicenter would have
around 15
seconds of lead time to prepare for an earthquake’s impact,
the time difference
between the arrival of the first P wave at a recording station near the
epicenter and the arrival of the S wave at the city itself. In
the study, the researchers looked into the entire active seismic belt
of the
Mediterranean region, which includes varying geological and tectonic
systems
and faults. They compared signals from both P and S waves from more
than 200
earthquakes and found that stress release and/or slip duration on the
fault in
the very early stage of seismic fracture relates both to the observed
peak
amplitude of the early P wave and to the elastic energy available for
propagation of the fracture. Although
relatively few magnitude 7 earthquakes have hit the study area in
recent years,
there have been many instances of quakes in the magnitude 6 range. (A
magnitude
7 earthquake is over 30 times more energetic than one of magnitude 6.)
Zollo
notes that even magnitude 6 quakes can produce great damage, especially
in
urbanized areas and places where old structures were not built to
current
standards; this defines much of the Mediterranean basin and applies
also in
other areas. The
researchers say that installations as close as 50 kilometers (30 miles)
from
the epicenter could receive an earthquake warning 10 seconds prior to
the
arrival of the main body wave of an earthquake. Places further from the
epicenter would have additional time, though still measured in seconds.
To take
advantage of this brief warning period, automated systems would have to
be
created that respond instantly to notification alert signals, and they
would
have to be carefully calibrated to avoid missed or false alarms. Engineers
note that in tall buildings, the higher floors sway much more than
those near
ground level, so that even a moderate earthquake could cause severe
damage to a
high-rise building, Zollo says. Therefore, even at 70–80
kilometers (40–50
miles) distance from its epicenter, a magnitude 6 quake could affect
hospital
operating rooms and other critical installations. Closer
to the epicenter, a magnitude 6 or higher earthquake can damage
critical
infrastructure, such as telephone lines, gas pipelines, highways, and
railroads, as well as airport runways and navigation systems. These
disruptions
would have a domino effect in more distant areas, which could be
mitigated by
an early warning alert system, based on the earliest primary wave data
to
arrive at recording stations close to the epicenter. The
researchers note that earthquake early warning systems can also help
mitigate
the effects of such earthquake-induced disasters as fires, explosions,
landslides, and tsunamis, which can in many cases be more devastating
than the
earthquake itself. Systems could be installed at relatively low cost in
developing countries, where moderate sized earthquakes can cause damage
comparable to that caused by much larger earthquakes in developed
countries,
they say. The
study was funded in part by the consortium Analisi e Monitoraggio del
Rischi
Ambientali (AMRA) scarl through the European Union-Seismic Early
Warning for ##
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