EPFL researchers have developed an optical fibre capable of detecting what sort of material or liquid they have come into contact with. Their research has been published in Nature Communications. In recent years optical fibres have served as sensors to detect changes in temperature, like a thermometer, and pressure, like an artificial nerve. This technique is particularly useful in structures such as bridges and gas pipelines.
EPFL researchers have now come up with a new method that enables optical fibres to identify whether they are in contact with a liquid or a solid. This is achieved by simply generating a sound wave with the help from a light beam within the fibre.
This study was conducted by the Group for Fibre Optics (GFO) run by Luc Thévenaz within the School of Engineering and has been published in Nature Communications.
No wider than a strand of hair, an optical fibre made of glass transmits light that varies according to four parameters: intensity, phase, polarisation and wavelength. These parameters are altered when the fibre is stretched or the temperature changes, enabling the fibre to act like a sensor by detecting cracks in structures or abnormal temperatures.
But up to now it was not possible to determine what was happening around the fibre without having light escape the fibre, which disrupts its path.
The method developed at EPFL uses a sound wave generated inside the fibre. It is a hyper-frequency wave that regularly bounces off the fibre’s walls. This echo varies at different locations depending on the material the wave comes into contact with.
The echoes leave an imprint on the light that can be read when the beam exits the fibre, making it possible to map out the fibre’s surroundings. This imprint is so faint that it hardly disturbs the light propagating within the fibre. The method could be used to sense what is going on around a fibre and send light-based information at the same time.
The researchers have already immersed their fibres in water and then in alcohol, before leaving them out in the open air. Each time, their system was capable of correctly identifying the change in the surroundings.
“Our technique will make it possible to detect water leakages, as well as the density and salinity of fluids that come into contact with the fibre. There are many potential applications,” said Thévenaz.
These changes in the surroundings are located thanks to a simple time-based method. “Each wave impulse is generated with a slight time lag. And this delay is reflected upon the beam’s arrival. If there were any disturbances along the way, we can both see what they were and determine their location,” explained Thévenaz.
“For the moment, we can locate disturbances to within around ten meters, but we have the technical means to increase our accuracy to one meter.”
The idea of using a sound wave in optical fibres initially came from the team’s partner researchers at Bar-Ilan University in Israel. Joint research projects should follow.