New research shows that a big earthquake can not only cause others, but large ones, and on the opposite side of the Earth. Their findings were published in Nature Scientific Reports, and are an important step toward improved short-term earthquake forecasting and risk assessment. Scientists at Oregon State University looked at 44 years of seismic data and found clear evidence that temblors of magnitude 6.5 or larger trigger others of magnitude 5.0 or larger.
It had been thought that aftershocks — smaller magnitude quakes that occur in the same region as the initial one as the surrounding crust adjusts after the fault perturbation — and smaller ones at great distances were the main global effects of very large earthquakes. But the OSU analysis of seismic data from 1973 through 2016 — an analysis that excluded data from aftershock zones using larger time windows than in previous studies — provided discernible evidence that in the three days following one large event, others were more likely to occur.
Each test case in the study represented a single three-day window “injected” with a large-magnitude (6.5 or greater) earthquake suspected of inducing others, and accompanying each case was a control group of 5,355 three-day periods that didn’t have the injection. The study’s corresponding author, Robert O’Malley, a researcher in the OSU College of Agricultural Sciences, said in a statement:
“The test cases showed a clearly detectable increase over background rates.
“Earthquakes are part of a cycle of tectonic stress buildup and release. As fault zones near the end of this seismic cycle, tipping points may be reached and triggering can occur.”
Higher magnitute quakes more likely to trigger others
The higher the magnitude, the more likely a quake is to trigger others. Higher-magnitude events, which have been happening with more frequency in recent years, also seem to be triggered more often than lower-magnitude ones. A tremblor is most likely to induce another one within 30 degrees of the original’s antipode — the point directly opposite it on the other side of the globe. O’Malley said:
“The understanding of the mechanics of how one earthquake could initiate another while being widely separated in distance and time is still largely speculative.
“But irrespective of the specific mechanics involved, evidence shows that triggering does take place, followed by a period of quiescence and recharge.”
Magnitude is measured on a logarithmic 1-10 scale — each whole number represents a 10-fold increase in measured amplitude and a 31-fold increase in released energy. The largest recorded earthquake was a 1960 temblor in Chile that measured 9.5. The 2011 quake that ravaged the Fukushima nuclear power plant in Japan measured 9.0.
In 1700, an approximate magnitude 9.0 earthquake hit the Cascadia Subduction Zone — a fault that stretches along the West Coast of North American from British Columbia to California.
Collaborating with O’Malley were Michael Behrenfeld of the College of Agricultural Sciences, Debashis Mondal of the College of Science, and Chris Goldfinger of the College of Earth, Ocean, and Atmospheric Sciences.
Provided by: Steve Lundeberg, Oregon State University [Note: Materials may be edited for content and length.]
Follow us on Twitter, Facebook, or Pinterest