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Rochester researchers achieve strong optical-acoustic interactions with long-lived acoustic waves.

When optical beams, consisting of photons, travel through fibers, they cause vibrations that generate acoustic waves, consisting of phonons. The phenomenon, called Brillouin scattering, has been harnessed by researchers to optomechanically 鈥渃ouple鈥� acoustic waves with light waves. This coupling allows information carried by photons to be transduced, or converted, to the phonons, which travel nearly a million times more slowly than light waves.

Opto-acoustic coupling has enabled researchers to read and manipulate the transduced information more easily. To date, however, many of the Brillouin scattering techniques researchers have used rely on standard fiber geometries that cause acoustic waves to die out quickly, limiting the efficacy of the coupling.

Now, using an optical fiber with a micron-sized waist, researchers have demonstrated how to couple propagating optical waves and long-lived acoustic waves, with strong optical-acoustic聽interactions.

鈥淭his is a unique and desirable combination that has not previously been achieved,鈥� says Wendao Xu, a PhD candidate in the research group of , assistant professor at Rochester鈥檚 . Xu is the lead author of a describing the breakthrough.

The breakthrough enables information carried by a light pulse to be temporarily stored in slowly propagating acoustic waves long enough for a second pulse of light to 鈥渞ead鈥� the information. The achievement could have applications for light storage, radio-frequency photonics filtering, and optical delay lines.

The research received Best Presentation Award at the WOMBAT 2022 Workshop on Optomechanics and Brillouin Scattering at the , where it was presented by coauthor Arjun Iyer, also a PhD candidate in .

鈥淲endao, Arjun, and our collaborators at the University of Tokyo did a great job in demonstrating the promise of this new platform and we are all excited as we begin focusing on next generation devices and real-world applications,鈥� Renninger says.

Brillouin scattering in optical fibers: overcoming challenges

鈥淭he amplitude of the acoustic wave keeps decreasing as it travels,鈥� Xu explains. 鈥淏asically, all the high-impact Brillouin scattering that people are dealing with right now produce strong interactions, but the acoustic waves are high in frequency, in the gigahertz range. The higher the frequency, the shorter the wave can actually travel before it dies out.鈥�

Xu鈥檚 tapered optical fiber device achieves both strong interactions and longer acoustic lifetimes. It consists of a multi-mode glass fiber with the cladding (coating) removed. By heating the center of the fiber and simultaneously applying mechanical tension to stretch the fiber at both ends, Xu and his collaborators produced a tightly confined, symmetrical 鈥渨aist鈥� in the fiber.

This waist provides 鈥渁n ideal optomechanical overlap yielding the strongest Brillouin coupling strengths observed to date from a fiber taper, and comparable to the largest optomechanical coupling strength for any system,鈥� the paper notes.

Moreover, the lifetime of the phonons that the device generates鈥攁bout 2 microseconds鈥攊s long enough that information carried by a light pulse can be temporarily stored in this slowly propagating acoustic wave for a relatively long period of time, before a second pulse of light reads the information.

A tapered optical fiber device

According to Iyer, Xu鈥檚 achievement is twofold. 鈥淥ne is the system, the tapered fiber device, which supports an acoustic wave family that people didn鈥檛 pay a lot of attention to previously,鈥� he says. 鈥淭he other is the process itself, using an interaction between two different optical spatial modes to get what we wanted.鈥�

The process鈥攊ncluding the physics involved in achieving strong interactions with long phonon lifetimes鈥攃ould be adapted and applied immediately to improve existing technologies, he says. For example, detecting and filtering out unwanted radio frequencies in photonic filters, or producing fiber-optic transmission delays to compensate for delay differences in optical fiber systems.

The tapered fiber system, on the other hand, while useful for research, is likely too fragile for real world applications outside the lab, Iyer says. 鈥淭hese are micron-sized filaments of glass that are just hanging there,鈥� he says.

However, the researchers are already exploring ways to package the system for real world applications, Iyer says.

Other collaborators include Lei Jin and Sze Y. Set at the 糖心logo Center for Advanced Science and Technology at the University of Tokyo. The research was supported with funding from the University of Rochester and National Science Foundation. The University of Rochester鈥檚 Integrated Nanosystems Center provided expertise and assistance with the SEM (scanning electron microscope) characterization of the taper device.

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