“First, we looked at the raw data transmitted via our channel and could see a better signal with our method, than without it,” he said.
“In our experiment, we first sent a photon through the loss – this photon is not carrying any useful information so losing it was not a big problem.
“We could then correct for the effects of loss via a device called noiseless linear amplifier developed at Griffith and the University of Queensland.
“It can recover the lost quantum state, but it cannot always succeed; sometimes it fails.
“However, once the recovery succeeds, we then use another purely quantum protocol – called quantum state teleportation – to teleport the information we wanted to transmit into the now corrected carrier, avoiding all the loss on the channel.”
Quantum technologies promise revolutionary changes in our information-based society, and a quantum communication develops methods such as the one demonstrated in this study to transmit data in an extremely secure and safe way, so that it is impossible to access by a third party.
“Short-distance quantum encryption is already used commercially, however if we want to implement a global quantum network, photon loss becomes in issue because it is unavoidable,” Dr. Slussarenko said.
“Our work implements a so-called quantum relay, a key ingredient of this long-distance communication network.
“The no cloning theorem forbids making copies of unknown quantum data, so if a photon that carries information is lost, the information it carried is gone forever.
“A working long-distance quantum communication channel needs a mechanism to reduce this information loss, which is exactly what we did in our experiment.”
Dr. Slussarenko said the next step in this study would be to reduce the errors to a level where the team could implement long-distance quantum cryptography, and test the method using real-life optical infrastructure, such as those used for fiber-based internet.
The findings have been published in the journal Nature Communications.
Reference: “Quantum channel correction outperforming direct transmission” by Sergei Slussarenko, Morgan M. Weston, Lynden K. Shalm, Varun B. Verma, Sae-Woo Nam, Sacha Kocsis, Timothy C. Ralph and Geoff J. Pryde, 5 April 2022, Nature Communications.
DOI: 10.1038/s41467-022-29376-4