Date:
March 28, 2014
Source:
Helmholtz Centre Potsdam - GFZ German
Research Centre for Geosciences
Summary
The largest earthquakes occur where
oceanic plates move beneath continents. Water trapped in the boundary between
both plates has a dominant influence on the earthquake rupture process.
Analyzing the great Chile earthquake of February, 27th, 2010, a group of
scientists found that the water pressure in the pores of the rocks making up the
plate boundary zone takes the key role.
Earthquake History of Chile
The largest earthquakes occur where oceanic plates move beneath continents. Obviously, water trapped in the boundary between both plates has a dominant influence on the earthquake rupture process. Analyzing the great Chile
earthquake of February, 27th, 2010, a group of scientists from the GFZ German
Research Centre for Geosciences and from Liverpool University found that the
water pressure in the pores of the rocks making up the plate boundary zone takes
the key role.
The stress build-up before an earthquake and the magnitude of subsequent
seismic energy release are substantially controlled by the mechanical coupling
between both plates. Studies of recent great earthquakes have revealed that the
lateral extent of the rupture and magnitude of these events are fundamentally
controlled by the stress build-up along the subduction plate interface. Stress
build-up and its lateral distribution in turn are dependent on the distribution
and pressure of fluids along the plate interface.
"We combined observations of several geoscience disciplines -- geodesy,
seismology, petrology. In addition, we have a unique opportunity in Chile that
our natural observatory there provides us with long time series of data," says
Onno Oncken, director of the GFZ-Department "Geodynamics and Geomaterials."
Earth observation (Geodesy) using GPS technology and radar interferometry today
allows a detailed mapping of mechanical coupling at the plate boundary from the
Earth's surface. A complementary image of the rock properties at depth is
provided by seismology. Earthquake data yield a high resolution
three-dimensional image of seismic wave speeds and their variations in the plate
interface region. Data on fluid pressure and rock properties, on the other hand,
are available from laboratory measurements. All these data had been acquired
shortly before the great Chile earthquake of February 2010 struck with a
magnitude of 8.8.
"For the first time, our results allow us to map the spatial distribution of the fluid pressure with unprecedented resolution showing how they control mechanical locking and subsequent seismic energy release," explains Professor Oncken.
"Zones of changed seismic wave speeds reflect zones of reduced mechanical coupling between plates." This state supports creep along the plate interface. In turn, high mechanical locking is promoted in lower pore fluid pressure domains. It is these locked domains that subsequently ruptured during the Chile earthquake releasing most seismic energy causing destruction at Earth's surface and tsunami waves. The authors suggest the spatial pore fluid pressure variations to be related to oceanic water accumulated in an altered oceanic fracture zone within the Pacific oceanic plate. Upon subduction of the latter beneath South America the fluid volumes are released and trapped along the overlying plate interface, leading to increasing pore fluid pressures. This study provides a powerful tool to monitor the physical state of a plate interface and to forecast its seismic potential.
"For the first time, our results allow us to map the spatial distribution of the fluid pressure with unprecedented resolution showing how they control mechanical locking and subsequent seismic energy release," explains Professor Oncken.
"Zones of changed seismic wave speeds reflect zones of reduced mechanical coupling between plates." This state supports creep along the plate interface. In turn, high mechanical locking is promoted in lower pore fluid pressure domains. It is these locked domains that subsequently ruptured during the Chile earthquake releasing most seismic energy causing destruction at Earth's surface and tsunami waves. The authors suggest the spatial pore fluid pressure variations to be related to oceanic water accumulated in an altered oceanic fracture zone within the Pacific oceanic plate. Upon subduction of the latter beneath South America the fluid volumes are released and trapped along the overlying plate interface, leading to increasing pore fluid pressures. This study provides a powerful tool to monitor the physical state of a plate interface and to forecast its seismic potential.
Story Source:
The above story is based on materials provided by Helmholtz Centre Potsdam - GFZ German Research Centre for Geosciences. Note: Materials may be edited for content and length.
The above story is based on materials provided by Helmholtz Centre Potsdam - GFZ German Research Centre for Geosciences. Note: Materials may be edited for content and length.
Journal Reference:
- Marcos Moreno et al. Subduction locking and fluid pressure distribution correlate before the 2010 Chile earthquake. Nature Geoscience, Vol. 7(2014), Issue 4, pp. 292-296 DOI: 10.1038/NGEO2102, 28.03.2014
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