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Quantum Metasurfaces Manipulate Free Photons

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A team at Los Alamos National Laboratory proposes that modulated quantum metasurfaces can control all properties of photonic qubits. According to the team, such a breakthrough would affect the fields of quantum information, communications, sensing, imaging, and energy and momentum harvesting. 

“People have studied classical metasurfaces for a long time,” said Diego Dalvit of the Physics of Condensed Matter and Complex Systems group in the laboratory’s Theoretical Division. “But we came up with this new idea, which was to modulate in time and space the optical properties of a quantum metasurface that allow us to manipulate, on demand, all degrees of freedom of a single photon.”
A metasurface with all-optical modulation of the refractive index induces color-spin-path quantum entanglement on a transmitted single photon. Courtesy of Los Alamos National Laboratory.
A metasurface with all-optical modulation of the refractive index induces color-spin-path quantum entanglement on a transmitted single photon. Courtesy of Los Alamos National Laboratory.

The team described the metasurface it developed as looking like an array of rotated crosses, which it can then manipulate with lasers or electrical pulses. Team members then proposed to shoot a single photon through the metasurface, where the photon splits into a superposition of many colors, paths, and spinning states that are all intertwined, generating so-called quantum entanglement — meaning that the single photon is capable of inheriting all these different properties at once.

“When the metasurface is modulated with laser or electrical pulses, one can control the frequency of the refracted single photon, alter its angle of trajectory, the direction of its electrical field, as well as its twist,” said Abul Azad from the Center for Integrated Nanotechnologies at the laboratory’s Materials Physics and Applications Division.

In manipulating these properties, the technology could be used to encode information in photons traveling within a quantum network. Encoding photons is particularly desirable in cryptography, as hackers are unable to view a photon without changing its fundamental physics, which would alert the sender and receiver that the information has been compromised.

The researchers are also working on how to pull photons from a vacuum by modulating the quantum metasurface.

“The quantum vacuum is not empty but full of fleeting virtual photons. With the modulated quantum metasurface, one is able to efficiently extract and convert virtual photons into real photon pairs,” said Wilton Kort-Kamp, in the Theoretical Division at the lab’s Physics of Condensed Matter and Complex Systems group.

Harnessing photons that exist within the vacuum and firing them in one direction should create propulsion in the opposite direction. Similarly, stirring the vacuum should create rotational motion from the twisted photons. Structured quantum light could then one day be used to generate mechanical thrust, using only tiny amounts of energy to drive the metasurface.

The research was published in Physics Review Letters (www.doi.org/10.1103/PhysRevLett.127.043603).

Photonics Handbook
GLOSSARY
quantum
Smallest amount into which the energy of a wave can be divided. The quantum is proportional to the frequency of the wave. See photon.
photon
A quantum of electromagnetic energy of a single mode; i.e., a single wavelength, direction and polarization. As a unit of energy, each photon equals hn, h being Planck's constant and n, the frequency of the propagating electromagnetic wave. The momentum of the photon in the direction of propagation is hn/c, c being the speed of light.
Research & TechnologyquantumlasersFiber Optics & Communicationsphotonopticsmetasurfacequantum lightentangledentangled LightEntangled photonssuperpositionsuperpositionssuperposition stateLos AlamosLos Alamos National LabLos Alamos National Laboratoryquantum communicationPhysical Review LettersqubitqubitsAmericas

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