Circulators are important for routing light in optical communications. However, they typically require centimeter-sized magnets, which are difficult to miniaturize for use on optical chips. Researchers at AMOLF (Amsterdam, Netherlands), the University of Texas at Austin, and City University of New York have circumvented this problem with a microring resonator circulator that directionally routes light on an optical chip without using magnets.1
Circulators allow the transmission of information without loss among more than two nodes in a network. Circulators have several entrance and exit ports between which they route light in a particular way: light entering a particular port is forced to exit in a second port, but light entering that second port exits in a third port, and so on.
"Light propagation is symmetric in nature, which means if light can propagate from A to B, the reverse path is equally possible," says AMOLF group leader Ewold Verhagen. "We need a trick to break the symmetry. Usually this 'trick' is using centimeter-sized magnets to impart directionality and break the symmetric nature of light propagation. Such systems are difficult to miniaturize for use on photonic chips."
Mechanically vibrating glass ring
Verhagen and his colleagues create circulating behavior using a microscale glass ring resonator with a different trick. They let light in the ring interact with mechanical vibrations of the same structure. The researchers used this principle in earlier work to demonstrate one-way optical transmission. "By shining light of a control laser in the ring, light of a different color can excite vibrations through a force known as radiation pressure, but only if it propagates in the same direction as the control light wave," Verhagen says. "Since light propagates differently through a vibrating structure than through a structure that is standing still, the optical force breaks symmetry in the same way as a magnetic field would."
The challenge was to dictate the particular exit to which light can be routed, such that it always takes the next port. Careful control of the optical paths in the structure ensures that light from each input constructively interferes in exactly the right output. "We demonstrated this circulation in experiments, and showed that it can be actively tuned," says Mathew. "The frequency and power of the control laser allow the circulation to be turned on and off and change handedness."
The AMOLF device is the first magnet-free on-chip optical circulator. Although the research is fundamental in nature, it has many possible applications. "Devices like this could form building blocks for chips that use light instead of electrons to carry information, as well as for future quantum computers and communication networks," says Verhagen. "The fact that the circulator can be actively controlled provides additional functionality as the optical circuits can be reconfigured at will."
Source: https://amolf.nl/news/a-microscopic-roundabout-for-light
Reference
Ruesink, J. P. Mathew et al., Nature Communications (2018); doi: 10.1038/s41467-018-04202-y.

John Wallace | Senior Technical Editor (1998-2022)
John Wallace was with Laser Focus World for nearly 25 years, retiring in late June 2022. He obtained a bachelor's degree in mechanical engineering and physics at Rutgers University and a master's in optical engineering at the University of Rochester. Before becoming an editor, John worked as an engineer at RCA, Exxon, Eastman Kodak, and GCA Corporation.