Key takeaways
New research shows that metasurfaces could be used as strong linear quantum optical networks
This approach could eliminate the need for waveguides and other conventional optical components
Graph theory is helpful for designing the functionalities of quantum optical networks into a single metasurface
In the race toward practical quantum computers and networks, photons -- fundamental particles of light -- hold intriguing possibilities as fast carriers of information at room temperature. Photons are typically controlled and coaxed into quantum states via waveguides on extended microchips, or through bulky devices built from lenses, mirrors, and beam splitters. The photons become entangled - enabling them to encode and process quantum information in parallel - through complex networks of these optical components. But such systems are notoriously difficult to scale up due to the large numbers and imperfections of parts required to do any meaningful computation or networking.
Could all those optical components could be collapsed into a single, flat, ultra-thin array of subwavelength elements that control light in the exact same way, but with far fewer fabricated parts?
Optics researchers in the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) did just that. The research team led by Federico Capasso, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering, created specially designed metasurfaces -- flat devices etched with nanoscale light-manipulating patterns -- to act as ultra-thin upgrades for quantum-optical chips and setups.
The research was published in Science and funded by the Air Force Office of Scientific Research (AFOSR).
Capasso and his team showed that a metasurface can create complex, entangled states of photons to carry out quantum operations - like those done with larger optical devices with many different components.
"We're introducing a major technological advantage when it comes to solving the scalability problem," said graduate student and first author Kerolos M.A. Yousef. "Now we can miniaturize an entire optical setup into a single metasurface that is very stable and robust."
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