Quantum properties of light used to transmit information

Quantum properties of light used to transmit information

Technology News |
Researchers at the University of Rochester and Cornell University say they have taken an important step toward developing a communications network that exchanges information across long distances by using photons - key elements of quantum computing and quantum communications systems.
By Rich Pell

Share:

The researchers designed a nanoscale node made out of magnetic and semiconducting materials that could interact with other nodes, using laser light to emit and accept photons. The device, say the researchers, demonstrates a way to use quantum properties of light to transmit information – a key step on the path to the next generation of computing and communications systems, which promise faster, more efficient ways to communicate, compute, and detect objects and materials.

The nanoscale node consists of an array of 120-nanometer high pillars, which are themselves part of a platform containing atomically thin layers of semiconductor and magnetic materials. The array is engineered so that each pillar serves as a location marker for a quantum state that can interact with photons and the associated photons can potentially interact with other locations across the device – and with similar arrays at other locations.

This potential to connect quantum nodes across a remote network, say the researchers, capitalizes on the concept of entanglement, a phenomenon of quantum mechanics that, at its very basic level, describes how the properties of particles are connected at the subatomic level.

“This is the beginnings of having a kind of register, if you like, where different spatial locations can store information and interact with photons,” says Nick Vamivakas, professor of quantum optics and quantum physics at Rochester.

Building on previous work that uses layers of atomically thin materials on top of each other to create or capture single photons, the new device uses a novel alignment of tungsten diselenide (WSe2) draped over the pillars with an underlying, highly reactive layer of chromium triiodide (CrI3). Where the atomically thin, 12-micron area layers touch, the CrI3 imparts an electric charge to the WSe2, creating a “hole” alongside each of the pillars.

In quantum physics, a hole is characterized by the absence of an electron. Each positively charged hole also has a binary north/south magnetic property associated with it, so that each is also a nanomagnet.

When the device is bathed in laser light, further reactions occur, turning the nanomagnets into individual optically active spin arrays that emit and interact with photons. Whereas classical information processing deals in bits that have values of either 0 or 1, say the researchers, spin states can encode both 0 and 1 at the same time, expanding the possibilities for information processing.

“Being able to control hole spin orientation using ultrathin and 12-micron large CrI3, replaces the need for using external magnetic fields from gigantic magnetic coils akin to those used in MRI systems,” says graduate student Arunabh Mukherjee, lead author of a paper on the research. “This will go a long way in miniaturizing a quantum computer based on single hole spins.”

In creating the device, the researchers say they faced two major challenges: One was creating an inert environment in which to work with the highly reactive CrI3, while the other was determining just the right configuration of pillars to ensure that the holes and spin valleys associated with each pillar could be properly registered to eventually link to other nodes.

The first challenge was overcome through collaboration with Cornell University researchers, whose expertise in working with chromium triiodide enabled fabrication of the CrI3 in nitrogen-filled glove boxes to avoid oxygen and moisture degradation. The second challenge, say the researchers, remains to find a way to send photons long distances through an optical fiber to other nodes, while preserving their properties of entanglement.

“We haven’t yet engineered the device to promote that kind of behavior,” says Vamivakas. “That’s down the road.”

For more, see “Observation of site-controlled localized charged excitons in CrI3/WSe2 heterostructures.”

Related articles:
Quantum loop entangles photons over 52-mile fiber network
Quantum computing at room temps moves closer to reality
Quantum system detects ultra-faint communications signals
Practical photon source for quantum communication
Quantum coding source promises transport of entangled photons from satellites

 

Linked Articles
Smart2.0
10s