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USTC develops all-optically controlled non-reciprocal multifunctional photonic devices
USTC Microcavity Research Group in the Key Laboratory of Quantum Information have perfected a 4-port all-optically controlled non-reciprocal multifunctional photonic device based on a magnetic-field-free optomechanical resonator is demonstrated for the first time. This achievement was published online in Nature Communications on May 4.
Light has bidirectional transmission reciprocity in common dielectric material, and breaking this reciprocity, that is, achieving non-reciprocity in the direction of light transmission, is of great significance in classical and quantum information processing. Optical circulators, isolators, directional amplifiers, etc. are typical non-reciprocal devices. The optical circulator allows light to be transmitted in a unirotational fashion between its ports, which can be used for light source protection and precise measurement. The directional amplifiers in quantum computing based on superconducting circuits are also very important. The most common optical non-reciprocal devices are based on the Faraday effects using magneto-optical materials, which are difficult to integrate on-chip. Therefore, in recent years, interest has increased in realizing on-chip all-optical circulators, isolators, and directional amplifiers.
In 2016, DONG Chunhua’s group experimentally demonstrated the optomechanically induced non-reciprocity in a whispering gallery mode microcavity [Nature Photonics 10, 657-661 (2016)]. On this basis, the group use a single cavity coupled with dual waveguides to implement a 4-part versatile photonic device, including the functions of narrow-band filter, four-port optical circulator and directional amplifier. The function mode can be switched arbitrarily by changing the control light. For the circulator, the signal light incident from the ports 1, 2, 3 and 4, exits from the ports 2, 3, 4 and 1, respectively, constituting a 1-2-3-4-1 circular path. When only focusing on ports 1 and 2, it is also an efficient optical isolator; for directional amplifiers, signal light incident from port 1 is amplified and exits from port 2, not the other way around. Thus in the direction of 1-2 has directional amplification. The demonstrated device can even realize optical circulators with single-photon level, and can be generalized to microwave and acoustic circuits.
Figure 1: Schematic of the optomechanical circulator and directional amplifier, image from SHEN Zhen.
SHEN Zhen, ZHANG Yanlei and CHEN Yuan are the co-first authors of this paper, with DONG Chunhua, ZOU Changling and SUN Fangwen as corresponding authors. The paper is funded by Ministry of Science and Technology, National Natural Science Foundation of China and Chinese Academy of Sciences.
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