Massive earthquakes won't go undetected with new method

New Delhi: Scientists have devised a method that can be helpful in estimating the magnitude of extremely large earthquakes.

This new gravity-based approach can be much more effective than the present, in which scientists make use of seismic waves from a rupture to work out the scale of the event.

However, a new analysis of the 2011 Tohoku earthquake in Japan by researchers from Paris Diderot University in France and California Institute of Technology in the US shows that changes in gravity can give more rapid information.

After an earthquake, there is an instantaneous gravitational disturbance that could be recorded before the seismic waves that seismologists can detect.

In a study published in the journal Science, researchers have managed to observe these weak signals related to gravity and to understand where they come from.

Since they are sensitive to the magnitude of earthquakes, these signals may play an important role in the early identification of the occurrence of a major earthquake.

Earthquakes brutally change the equilibrium of forces on Earth and emit seismic waves whose consequences can be devastating. However, these same waves also disturb the Earth's field of gravity, which produces a different signal.

This is particularly interesting with a view to fast quantification of tremors, because it moves at the speed of light, unlike tremor waves, which propagate at speeds between three and 10 kilometres per second, researchers said.

Seismometers at a station located 1,000 km from the epicentre may potentially detect this signal more than two minutes before the seismic waves arrive, they said.

First, the scientists observed these signals on the data from about 10 seismometers located between 500 and 3,000 km from the epicentre of the 2011 Japanese earthquake (magnitude 9.1).

The researchers then demonstrated that these signals were due to two effects. The first is the gravity change that occurs at the location of the seismometer, which changes the equilibrium position of the instrument's mass.

The second effect, which is indirect, is due to the gravity change everywhere on Earth, which disturbs the equilibrium of the forces and produces new seismic waves that will reach the seismometer.

(With Agency inputs)