Tuesday, January 23, 2018

Researchers use sound waves to advance optical communication

Illinois researchers have demonstrated that #soundwaves can be used to produce #ultraminiature #opticaldiodes that are tiny enough to fit onto a #computer #chip. These devices, called #opticalisolators, may help solve major data capacity and system size challenges for photonic integrated circuits, the light-based equivalent of electronic circuits, which are used for computing and communications. Researchers use sound waves to advance optical communication Champaign, IL | Posted on January 22nd, 2018 blog posts CHAMPAIGN, Ill. —Illinois researchers have demonstrated that sound waves can be used to produce ultraminiature optical diodes that are tiny enough to fit onto a computer chip. These devices, called optical isolators, may help solve major data capacity and system size challenges for photonic integrated circuits, the light-based equivalent of electronic circuits, which are used for computing and communications. Isolators are nonreciprocal or “one-way” devices similar to electronic diodes. They protect laser sources from back reflections and are necessary for routing light signals around optical networks. Today, the dominant technology for producing such nonreciprocal devices requires materials that change their optical properties in response to magnetic fields, the researchers said. “There are several problems with using magnetically responsive materials to achieve the one-way flow of light in a photonic chip,” said mechanical science and engineering professor and co-author of the study Gaurav Bahl. “First, industry simply does not have good capability to place compact magnets on a chip. But more importantly, the necessary materials are not yet available in photonics foundries. That is why industry desperately needs a better approach that uses only conventional materials and avoids magnetic fields altogether.” In a study published in the journal Nature Photonics, the researchers explain how they use the minuscule coupling between light and sound to provide a unique solution that enables nonreciprocal devices with nearly any photonic material. However, the physical size of the device and the availability of materials are not the only problems with the current state of the art, the researchers said. “Laboratory attempts at producing compact magnetic optical isolators have always been plagued by large optical loss,” said graduate student and lead author Benjamin Sohn. “The photonics industry cannot afford this material-related loss and also needs a solution that provides enough bandwidth to be comparable to the traditional magnetic technique. Until now, there has been no magnetless approach that is competitive.” The new device is only 200 by 100 microns in size – about 10,000 times smaller than a centimeter squared – and made of aluminum nitride, a transparent material that transmits light and is compatible with photonics foundries. “Sound waves are produced in a way similar to a piezoelectric speaker, using tiny electrodes written directly onto the aluminum nitride with an electron beam. It is these sound waves that compel light within the device to travel only in one direction. This is the first time that a magnetless isolator has surpassed gigahertz bandwidth,” Sohn said.

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