Geophysicists at ETH Zurich have shown that every single wave of a magnitude 3.9 earthquake registers in the noise suppression system of fiber-optic networks. This method, now published in Scientific Reports, can be used to set up close-meshed earthquake and tsunami early warning systems at low cost.

For wealthy countries like Switzerland, having a dense network of earthquake monitoring stations is a matter of course. This is not the case in less developed countries and on the floor of the world’s oceans. While poorer regions lack the money for the necessary number of sensors, the oceans require complex systems that can reliably measure minimal pressure changes at depths of thousands of meters and bring the data signals to the surface.

Secondary use of noise suppression data

Scientists from the Institute of Geophysics at ETH Zurich, working together with the Swiss Federal Institute of Metrology (METAS), have now found an amazing and inexpensive method that enables accurate earthquake measurements even on the ocean floor and in less developed countries.

“We’re taking advantage of a function that existing fiber-optic infrastructure already performs: we obtain the vibration data from the active noise suppression system, which has the job of increasing the accuracy of the signals in optical data communication,” explains geophysics professor Andreas Fichtner. All that’s required is to store the active noise suppression data and evaluate it—no need for additional devices or expensive infrastructure.

Vibration ‘noise’ is extinguished

To understand how active phase noise cancellation (PNC) can measure seismic tremors, it helps to compare it with the noise suppression systems of today’s high-end headphones, which make the ambient noise almost completely disappear for users. These headphones feature microphones that pick up external noise. This signal is inverted and then fed into the audio signals practically in real time. The phase-inverted signal cancels out the external noise one-to-one, making it inaudible.

In the PNC of an optical data communication system, the “ambient noise” in the optical fiber is determined by comparing the originally transmitted signal with a partial signal that is reflected by the receiver. The difference between the two signals then indicates the interference to which the light signal was exposed on its way through the optical fiber. Just as with noise suppression in headphones, this interference can be cancelled out using an appropriate anti-signal.

Deformations cause minimal frequency changes

In optical data transmission, the “noise” is caused when optical fibers are perturbed by mere micrometers. This occurs in response to deformations of the Earth’s surface due to earthquakes, water waves, differences in air pressure and human activity. Each deformation shortens or lengthens the fiber slightly. This in turn leads to what is known as a photo-elastic effect, which causes the speed of light in the fiber to fluctuate ever so slightly.

Both the changes in fiber length and the fluctuations in the speed of light change the frequency of the light signal by a tiny factor. This phenomenon has been known for several years and has already been put to use in special instruments to measure vibrations.

But in the case of the noise suppression system in the fiber-optic communication of Switzerland’s atomic clock infrastructure investigated by the scientists at ETH and METAS, such additional measuring instruments are superfluous: the deformations can be easily read from the correction of the time signals. This corrects the wavelength of the signal in the terahertz range (1012 oscillations per second) by a few hundred hertz—in other words, by around a tenth of a billionth.

Exact match with Swiss Seismological Service

These changes might be tiny, but they paint an extremely clear picture of the vibrations to which the fiber-optic cables are exposed during the observation period. “Using the PNC of the fiber-optic link between Basel and the atomic clock site at METAS in Bern, we were able to track every single wave of a magnitude 3.9 earthquake in Alsace in detail,” Fichtner explains. “But even better, a model of the quake based on our data also corresponded extremely accurately to the measurements taken by the Swiss Seismological Service.”

This nearly exact match shows that the PNC data can be used to determine an earthquake’s location, depth and magnitude with a high degree of accuracy. “This is particularly interesting for comprehensive tsunami warnings or for measuring earthquakes in less developed regions of the world,” Fichtner says.

For Fichtner, the story of how the new method was developed is also exemplary. The idea arose from a discussion between ETH researchers and a specialist at METAS. As soon as the ETH-METAS team recognized the potential of the PNC data, they quickly implemented the idea.

“For surprising science to emerge, there have to be funds available for research activities that don’t pursue a predefined goal,” Fichtner says. “ETH is ideal for that kind of project. In contrast to many other universities, I have unrestricted funds available to me as a researcher here.”

More information: Sebastian Noe et al, Long-range fiber-optic earthquake sensing by active phase noise cancellation, Scientific Reports (2023). DOI: 10.1038/s41598-023-41161-x

Journal information: Scientific Reports

Provided by ETH Zurich