Improved single photon switch
16.08.2021 - A first step towards realizing chip-scale scalable single photon switches.
The ability to turn on and off a physical process with just one photon is a fundamental building block for quantum photonic technologies. Realizing this in a chip-scale architecture is important for scalability, which amplifies a breakthrough by City College of New York researchers led by physicist Vinod Menon. They've demonstrated for the first time the use of Rydberg states in solid state materials to enhance nonlinear optical interactions to unprecedented levels in solid state systems. This feat is a first step towards realizing chip-scale scalable single photon switches.
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Schematic of the optical microcavity with 2D semiconductor. The nonlinear optical response arises from the larger Bohr radii Rydberg excitons allowing to push the limit to few photon nonlinear limit. (Source: R. Bushati)
In solid state systems, exciton-polaritons, half-light half-matter quasiparticles, which result from the hybridization of electronic excitations and photons, are an attractive candidate to realize nonlinearities at the quantum limit. “Here we realize these quasiparticles with Rydberg excitons in atomically thin semiconductors,” said Menon, chair of physics in City College's Division of Science. “Excited states of excitons owing to their larger size, show enhanced interactions and therefore hold promise for accessing the quantum domain of single-photon nonlinearities, as demonstrated previously with Rydberg states in atomic systems.”
According to Menon, the demonstration of Rydberg exciton-polaritons in two-dimensional semiconductors and their enhanced nonlinear response presents the first step towards the generation of strong photon interactions in solid state systems, a necessary building block for quantum photonic technologies. “The research of Menon and his co-workers could have a tremendous impact on Army goals for ultra-low energy information processing and computing for mobile Army platforms such as unmanned systems,” said Michael Gerhold, program manager at the U.S. Army Combat Capabilities Development Command, DEVCOM, Army Research Laboratory. “Optical switching and nonlinearities used in future computing paradigms that use photonics would benefit from this advancement. Such strong coupling effects would reduce energy consumption and possibly aid computing performance.” (Source: CCNY)
Link: Dept. of Physics, City College of New York, New York, USA
