Opto-mechanical non-reciprocity in fiber

Opto-mechanical non-reciprocity in fiber
a, Schematic cross-section of a "panda-type" fiber. Two strain rods induce strain in the fiber, and distinguish between propagation in "slow" and "fast" axes. b, Profile of material displacement of an acoustic wave supported by the panda fiber cross-section. c, Measurement and calculations of the spectrum of acoustic waves that are driven by light in the panda fiber. The acoustic waves are stimulated by a pair of optical tones: one polarized along the fast axis and the other along the slow one. d, Switching of optical probe waves between fast and slow axes. The switching of polarization can be induced at specific wavelengths (horizontal axis), through acoustic waves of specific frequencies (vertical axis). The switching effect is non-reciprocal: it takes place for one direction of propagation of the optical probe wave along the fiber, but not for the opposite one. Credit: Gil Bashan, Hilel Hagai Diamandi, Yosef London, Kavita Sharma, Keren Shemer, Elad Zehavi and Avi Zadok

The internet era that we live in depends completely on the transfer of vast amounts of information over optical fibers. Optical fibers are literally everywhere. In fact, the overall length of optical fibers installed on our planet is sufficient to reach planet Uranus and back. However, the transfer of information from point A to point B is not enough. The information that we send and receive must also be processed. Light waves take up an increasing role in addressing that task.

In addition, optical fibers can do more for us than just relay information: They constitute an exceptional sensing platform. Optical fibers support measurements from a long stand-off distance, are simply installed within structures, and are suitable for hazardous environments. Optical fibers also support spatially distributed mapping, in which every section serves as an independent node of a sensory network. In both and sensing tasks, the operation of optical fibers can be significantly aided by another factor that may be surprising: ultrasound.

Prof. Avi Zadok from the Faculty of Engineering of Bar-Ilan University, Israel, explains that "we are accustomed to think of the and ultrasound as two separate realms. However, this would be an oversimplification. The of down a fiber, for example, can excite ultrasonic elastic waves. At the same time, the same ultrasonic waves affect and scatter light." Such inter-relation goes beyond an academic exercise, Prof. Zadok continues. "Ultrasound waves can make optical fibers do a better job. They can help us select specific information that belongs to specific users. They can also perform sensing measurements beyond the boundaries of the fiber itself, where light does not reach." The formulation and employment of such interaction between light and sound waves is therefore of much potential consequence.

In a paper published recently in Light: Science and Applications, a team of researchers from Prof. Zadok's group analyze and measure the interplay of light and ultrasound in a particularly interesting class of fibers. Doctoral student Gil Bashan explains that "the most standard optical fibers are called single-mode fibers. In those, the opportunities for tailoring the light-and-ultrasound interplay are rather limited. In this study we turned to fibers that are called polarization maintaining, or PM fibers. Such fibers are still readily available and employed on a very large scale, so there is no difficulty of gaining access to them. However, they give us more options to play with."

They key factor in PM fibers is that like can propagate in two different ways. Bashan says that "light that is polarized in the vertical direction inside the fiber takes up a certain speed, however light that is polarized in the horizontal direction takes up another one. This property of PM fibers was not meant to assist in ultrasonics. Nevertheless, we find it very interesting and useful for our purposes. When light can be either 'fast' or 'slow' along the PM fiber, we have more options to chose from, and larger freedom to design and employ the interplay of light and ultrasound."

One particularly interesting result is the removal of symmetry between directions of propagation. Fellow student Hagai Diamandi explains that "in standard conditions, light should propagate the same way either from left to right, or from right to left. The physics knows no difference. The ultrasonic waves supported by PM fibers are able to change that. Once introduced, they may lead to non-reciprocity. Light in one direction gets switched between the vertical and horizontal states, but that does not happen at the opposite direction of propagation." Non-reciprocal propagation is fundamentally intriguing, but they may also assist in advanced sensor networks, as explained in. Diamandi concludes that "there have been brilliant reports on non-reciprocal propagation of light due to before. However previous demonstrations required specialty fibers or photonic circuits that are custom-made in research labs. These PM fibers come off the shelf."

More information: Gil Bashan et al, Forward stimulated Brillouin scattering and opto-mechanical non-reciprocity in standard polarization maintaining fibres, Light: Science & Applications (2021). DOI: 10.1038/s41377-021-00557-y

Journal information: Light: Science & Applications

Citation: Opto-mechanical non-reciprocity in fiber (2021, June 14) retrieved 20 April 2024 from https://phys.org/news/2021-06-opto-mechanical-non-reciprocity-fiber.html
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