Quantum internet a step closer with data storage breakthrough

Quantum internet a step closer with data storage breakthrough

Tuesday, September 12, 2017 — Scientists at The Australian National University (ANU) have found a new way to store quantum data long enough to share the information around a next-generation internet which promises to be impervious to hacking.

The work, published in Nature Physics, addresses a crucial challenge that has eluded researchers worldwide.

Lead researcher Associate Professor Matthew Sellars from the ANU Research School of Physics and Engineering said the improved storage was an important part of a viable quantum internet.

“The effort to build a quantum computer is often described as the space race of the 21st century,” said Dr Sellars, who is the Program Manager in the Centre for Quantum Computation and Communication Technology (CQC2T) at ANU.

“Our work will allow us to build a global network to connect quantum computers.”

The team used a rare earth element, called erbium, in a crystal to increase the storage time of telecom-compatible quantum memory by 10,000 times compared to previous efforts.

Erbium has unique quantum properties and operates in the same bandwidth as existing fibre optic networks, eliminating the need for a conversion process.

“We have shown that an erbium-doped crystal is the perfect material to form the building blocks of a quantum internet that will unlock the full potential of future quantum computers,” Dr Sellars said.

“We had this idea 10 years ago, but many of our peers told us that such a simple idea couldn’t work. Seeing this result, it feels great to know that our approach was the right one.”

Dr Rose Ahlefeldt from the ANU Research School of Physics and Engineering said quantum memory allowed scientists to buffer and synchronise quantum information, operations necessary for long- range and ultra-secure encrypted communications.

“At the moment researchers are using memories that don’t work at the right wavelength, and have to employ a complicated conversion process to and from the communications wavelength,” said Dr Ahlefeldt, who is a Discovery Early Career Research Award (DECRA) Fellow and is also from the CQC2T.

“This can be inefficient, and means they have to do three very difficult things instead of just one.”

First author and PhD scholar Miloš Rančić said the new technology can also be operated as a quantum light source or used as an optical link for solid-state quantum computing devices, connecting them to the quantum internet.

“Our technology can connect with many types of quantum computers including CQC2T’s silicon qubits and superconducting qubits, which Google and IBM are developing,” said Mr Rančić from the ANU Research School of Physics and Engineering and the CQC2T.

MATERIALS

STILLS: https://1drv.ms/f/s!Ao2X7nRblAZUgaRHvpPlnEBJlyKrzQ
VIDEO: https://youtu.be/e6RKKXiMWmg (unlisted until embargo lifts)
SCIENTIFIC MANUSCRIPT: https://1drv.ms/b/s!Ao2X7nRblAZUgaRKYSv6MMvH6KgI9w

FOR INTERVIEWS:

Associate Professor Matthew Sellars
ANU Research School of Physics and Engineering and the CQC2T
M: +61 455 777 710
E: matthew.sellars@anu.edu.au

Dr Rose Ahlefeldt
ANU Research School of Physics and Engineering and the CQC2T
M: +61 466 892 429
E: rose.ahlefeldt@anu.edu.au

To arrange interviews, contact Will Wright from ANU media on +612 6125 7979, +61 478 337 740 or media@anu.edu.au

Erbium: Building block for a global quantum internet