Post on 05-Jan-2016
Thinking about time variable seismic risk
Karen FelzerUSGS, Pasadena
A farmer suffering from low milk production asked for help from a team of academics at the local college..
After two weeks of hard work, the farmer received a report from the physicist leading the team, which started “Consider a
spherical cow...”
Earthquakes are really complex..
So there is a tendency to use lots of spherical cows…
One of the big “spherical cows” is imaging earthquakes as static processes
Static failure occurs when stress over the entire fault reaches failure strength
Is this spherical cow useful?
Yes, if the stress/strength ratio at the hypocenter and over the rest of the fault is similar
No, if the stress/strength ratio at the hypocenter and over the rest of the fault are dissimilar
Dissimilar stress/strength ratios are a problem because earthquakes are really dynamic processes, with rupture at one
point triggering rupture at the next
The stress/strength balance only needs to be satisfied at the hypocenter
After this high crack tip stresses can easily override initial conditions
The first domino
The evidence is very strong that the stress/strength ratio at the hypocenter is very different from the rest of the fault
Borehole measurements find hydrostatic pore pressure, frictional
coefficient ~0.6—1.0. This means that ~100MPa of shear stress should be
required to start rupture.
But a large amount of data indicates that the deviatoric stress on the fault at
rupture is no more than 10 MPa
Data limiting the stress on faults at rupture
Expectation: Decay of heat flow with distance from
the San Andreas fault
Observation: No variation of heat flow across the San
Andreas
Lachenbruch and Sass (1980)
Lack of a San Andreas heat flow anomaly
San Andreas observation later verified (Fulton et al. 2004) and observed around other major faluts (Kano et al, 2006)
Data limiting the stress on faults at rupture
Rotation of focal mechanisms by surrounding earthquakes indicates deviatoric stress <10 MPa
(Hardebeck and Haukkson, 2001; Hasegawa et al., 2011)
Focal mechanism rotation by
surrounding earthquakes over
time from Hardebeck and
Hauksson, (2001)
Data limiting the stress on faults at rupture
Direct borehole measurements of active faults show low stress (Zoback and Healy,
1992; Zoback and Harjes, 1997).
Data limiting the stress on faults at rupture
Earthquake stress drops are usually <10 MPa and there is significant evidence that static stress drops in earthquakes are near complete (Michael et al.1990; Beroza and Zoback, 1993; Hasegawa et al. 2011; Barton and Zoback, 1994)
Static stress drops tend to be <100 bars or <10 MPa, figure
from Abercrombie and Leary (1993).
High fault strength and low fault deviatoric stress mean that:
• After a minimum stress reloading period, most of the fault ruptures because of dynamic high fault tip stresses followed by dynamic weakening.
• The hypocenter must either be at much higher stress or much lower strength than the rest of the fault before rupture. Conditions at the hypocenter and rest of the fault are not similar, so the static approximation cannot be used.
Fault 1 + Hypocenter 1
How it really works
stre
ngth
stre
ngth
stress
stress
Fault 2 + Hypocenter 2
Before triggering, Fault 2 should rupture first
Hypocenter 1
stre
ngth
stre
ngth
stress
stressEarthquake!
But after a neighboring earthquake Fault 1
goes first
Fault 2 + Hypocenter 2
Failure!
Proposed short term hazard map
Thank you very much!
So – is there a place for renewal models?
• It is unlikely that linear stress renewal could operate at the hypocenter and no place else.
• There is data that indicates that forces from preceding earthquakes cause severe localized fault weakening at future hypocenters, allowing earthquakes to start there.
• If this is correct smoothed seismicity maps should be the best forecasters of short term seismicity – and they are ! (Schorlemmer et al., 2010)