Fiber optic seismic sensors from submarine cables

FBG sensors in seismologyA team of researchers from France proposes for the first time the opportunity to detect the propagation of seismic waves on the seafloor by fiber optic seismic sensors made from submarine telecommunications cables. The researchers confirm that the potential application of such seismic sensors includes the use of existing infrastructure for the detection of earthquakes, as well as swell and underwater noise.

It should be noted that about 1.2 million kilometers of telecommunications cables cut across the ocean floor that is equal to three times the distance from the Earth to the Moon. The cables consist of optical fibers leading to simple communication by phones, SMS, or e-mail. Herewith, the optical fibers could soon find a new application, that of detecting acoustic and seismic waves.

To be more precise, the researchers apply a 41 km-long fiber cable installed at the coast of Toulon in southern France for their tests to obtain data from the fiber optic sensors of the underwater observatory that is at a depth of 2500 m. Moreover, a special technique based on small impurities in the optical fibers is used for sending light back to the transmitter.

The thing is that “by stretching or contracting the optical fiber, the passage of a seismic or acoustic wave alters the distance between these impurities, and thus the backscattered signal, by a tiny amount.” Nonetheless, the researchers have to prove the opportunity to detect these differences in submarine fiber optic cables because of the insulating layers that surround the optical fibers.

Thus, the pulses of light put at the optical fiber and allow analyzing the backscattered signal. The researchers use the 41 km of optical fibers for tests and change them into more than 6000 fiber optic seismic sensors. Moreover, such fiber sensors enabled to detect a magnitude 1.9 earthquake that happened during the test at each of the sensing areas with a sensitivity close to that of a coastal seismic station, even despite the fact that it was located over 100 km from the fiber optic cable.

Nevertheless, the benefits of seismic sensors do not complete: the sensing points of fiber cable are highly sensitive to waves that go through the ocean, for instance, those created by the swell. The influence of waves on the seafloor near the coast, as well as the effect on the abyssal plain, where they produce “seismic background noise” was captured.

Finally, the fiber optic seismic sensors make it real to find out for the first time how the tiny vibrations that permanently interact with the Earth’s interior are created, allowing specialists in geophysics to examine its structure. Also, such fiber sensors may overcome a wide range of scientific and societal challenges like earthquakes, coastal erosion, the interaction between life, the oceans and the solid Earth, etc.

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Fiber Optic Sensors for Borehole seismic technology system

Seismic techniques are the main techniques for the characterization of subsurface structures and stratigraphy. Borehole technology system provides the highest resolution characterization and most precise monitoring results because it generates a higher signal to noise ratio and higher frequency data than surface seismic techniques. A new generation of fiber optic borehole sensor systems has been developed based on all fiber optic data transmission and fiber optic sensor technologies. The new fiber sensors are much more sensitive and are able to record much larger bandwidth data with better vector fidelity than is possible with current seismic sensor technologies. The new sensors also can operate in most hostile environments found in boreholes such as pressure and temperature conditions. This improvement in data quality and density will generate better images and more precise monitoring results, which will allow a much improved high-resolution interpretation and ultimately better oil and gas production.

Since the borehole seismic system does not require electric power for either the optical sensors or the hydraulically operated deployment system, the entire system is intrinsically safe. The fiber-optic seismic sensor system measures the strain of the fiber between two Fiber Bragg gratings surrounding the mandrel using an interferometric measurement technique comparing the phase angle between two spaced reflections from the same light pulse traveling in the fiber. It is using a time-division multiplexing technique to transmit the dynamic fiber strain information to the interrogators. This allows the measurement of extremely small strains in the fiber. The fiber optic seismic sensor is self-standing to electric and electromagnetic interference in the borehole since the system does not require any electronics at the fiber optic sensor end. This design also makes the fiber optic seismic sensor extremely robust and able to operate in extreme environments such as temperatures up to 300 C.  All the sensors are calibrated so the optical output amplitude into absolute acceleration can be mapped. The sensors have also proved to be about 100 times more sensitive than the regular coil geophones that are used in borehole seismic systems today.

Optromix Company manufactures a wide range of sensors, that are able to feel the slightest deformation of the structures.