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Holding the quantum keys, innovation helps keep the power grid safe

April 16th, 2024
Holding the quantum keys, innovation helps keep the power grid safe
Quantum equipment in the Alice laboratory, where the photon source and the first node in the team’s network are stored. Credit: Carlos Jones/ORNL, U.S. Dept. of Energy

Oak Ridge National Laboratory (ORNL) scientists have spent the past 20 years studying quantum photonic entanglement, which uses quantum mechanics to pair particles of light or photons and then employs those particles to encode and deliver information across long distances.

Their partnership with colleagues at Los Alamos National Laboratory (LANL) and private industry partner Qubitekk led to the development of the nation's first industry-led commercial quantum network. This type of network could ultimately help secure the nation's power grid and other infrastructure from cyberattacks.

"This technology allows us to take full advantage of quantum resources being developed all over the U.S.," said Nick Peters, head of ORNL's Quantum Information Science Section.

The effort began when the city of Chattanooga's Electric Power Board, or EPB, which provides power and data services to approximately 120,000 customers, approached ORNL in search of ways to make the local power grid more reliable and secure. The request gave ORNL and LANL researchers an opportunity to collaborate with Qubitekk and experiment with quantum-based secret keys on an isolated part of EPB's fiber-optic network.

Quantum computing uses quantum bits, or qubits, to store information. Qubits don't work the same way as the bits in classical computers—the types of computers we rely on today. Classical bits store information as one of two potential values—0 or 1—per bit, similar to a light switch that flicks on or off. Qubits store information using quantum superposition, which allows a combination of potential values to be stored on a single qubit, more like a dial with a range of settings than a switch.

"The goal is basically to enable us to do what we can't by any other means," Peters said. "That includes building larger telescopes that can see across greater distances and distributing quantum computers that can communicate across more secure networks."

The EPB effort employed quantum key distribution systems that use photons and quantum superposition to verify data and generate secret keys used to encrypt messages. One quantum system can transmit that key to another via a quantum node that's impervious to most cyberattacks.

"It's like sharing a secret password that nobody can guess," said Warren Grice, an ORNL senior research scientist. "When a security key is rooted in the randomness of quantum mechanics, it can't be broken by even the most powerful conventional computers. Our demos showed we can deploy this technology without interfering with general operations, so there's no interruption of anyone getting their power, phone service, or internet."

Quantum entanglement means the photons no longer operate independently, no matter how far apart they are.

Demonstrations found that the quantum systems could work together seamlessly even with different hardware and software elements, which means the approach could be adopted at a regional, state, or national level to protect the power grid.

"We can show it works, and we can show the benefits," Peters said. "We're excited to see where this technology takes us."

Provided by Oak Ridge National Laboratory

Citation: Holding the quantum keys, innovation helps keep the power grid safe (2024, April 16) retrieved 26 November 2024 from https://sciencex.com/wire-news/474737468/holding-the-quantum-keys-innovation-helps-keep-the-power-grid-sa.html
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