9 June 2021
Researchers Take Quantum Encryption Out of the Lab
Field trial shows simple QKD system works with existing telecommunication network in Italy
WASHINGTON — In a new study, researchers demonstrate an automated, easy-to-operate quantum key distribution (QKD) system using the fiber network in the city of Padua, Italy. The field test represents an important step toward implementing this highly secure quantum communication technology using the type of communication networks already in place in many regions around the world.
QKD offers impenetrable encryption for data communication because it uses the quantum properties of light to generate secure random keys for encrypting and decrypting data.
Caption: Researchers demonstrated a new simple QKD system over a fiber network in Padua, Italy. A map of the city center [©2021 Google] shows that the transmitter was placed at the ICT Center of UniPD while the receiver was located in the Department of Mathematics. The transmitter and the receiver were connected by 3.4 km of deployed fibers.
Credit: QuantumFuture Group, Università degli Studi di Padova
“QKD can be useful in any situation where security is paramount because it offers unconditional security for the key exchange process,” said Marco Avesani from Università degli Studi di Padova in Italy, co-first author of the new study with Luca Calderaro and Giulio Foletto. “It can be used to encrypt and authenticate health data sent between hospitals or money transfers among banks, for example.”
In The Optical Society (OSA) journal Optics Letters, researchers led by Paolo Villoresi and Giuseppe Vallone report that their simple system is stable over time and can generate quantum-secure cryptographic keys at sustained rates over a standard telecommunications infrastructure.
“QKD systems usually require a complex stabilization system and additional dedicated synchronization hardware,” said Avesani. “We developed a complete QKD system that can be
directly interfaced with standard telecommunications equipment and doesn’t require additional hardware for synchronization. The system fits easily into the rack enclosures commonly found in server rooms.”
Designing an easy-to-use system
To produce the quantum states required by QKD, the researchers developed a new encoder for manipulating the polarization of single photons. The encoder, which the researchers call iPOGNAC, provides a fixed and stable polarization reference that doesn’t require frequent recalibration. This feature is also advantageous for free-space and satellite quantum communication, where recalibrations are hard to perform.
“Because of the technology we developed, the source was ready to produce quantum states when we moved our system from the lab to the location of the field trial,” said Calderaro. “We didn’t have to perform the slow, and often prone-to-failure, alignment procedure required for most QKD systems.”
The researchers also developed a new synchronization algorithm, which they call
Qubit4Sync, to synchronize the machines of the two QKD users. Rather than using dedicated additional hardware and an added frequency channel for synchronization, the new system uses software and the same optical signals being used for QKD. This makes the system smaller, cheaper, and easier to integrate into an existing optical network.
To test the new system, the researchers brought their two QKD terminals to two university buildings roughly 3.4 km apart in different sections of Padua. They connected the systems to two underground optical fibers that are part of the university’s communication network. These fibers supported the quantum channel carrying qubits and the classical channel needed to transfer ancillary information.
Caption: The entire transmitter for the new QKD system fits in a 19-inch rack enclosure, which is commonly found in server rooms.
Credit: Luca Calderaro, Università degli Studi di Padova
A quantum-secured video call
“The field trial was successful,” said Foletto. “We showed that our simple system can produce secret keys at speeds of kilobits per second and that it works outside of the laboratory with little human intervention. It was also easy and quick to install.”
In a public demonstration, the researchers used their setup to enable a quantum-secured video call between the Rector of the University of Padua and the Director of the Mathematics Department. The researchers note that the system’s performance is comparable to other commercial QKD systems in terms of secret key generation rate while also having fewer components and being easier to integrate into an existing fiber network.
They are working to reduce the size of the detection apparatus and to make the system more robust to noise from other light traveling in the same fiber. The effort to develop a complete and autonomous QKD system led to the creation of a spin-off company called ThinkQuantum s.r.l, which is working to commercialize this technology.
Paper: M Avesani, L. Calderaro, G. Foletto, C. Agnesi, F. Picciariello, F. Santagiustina, A. Scriminich, A. Stanco, F. Vedovato, M. Zahidy, G. Vallone, P. Villoresi, “Resource-effective Quantum Key Distribution: a field trial in Padua city center,” Opt. Lett., 46, 12, 2848-2851(2021).
About Optics Letters
Optics Letters offers rapid dissemination of new results in all areas of optical science with short, original, peer-reviewed communications. Optics Letters accepts papers that are noteworthy to a substantial part of the optics community. Published by The Optical Society and led by Editor-in-Chief Miguel Alonso, Institut Fresnel, École Centrale de Marseille and Aix-Marseille Université, France, University of Rochester, USA. Optics Letters is available online at OSA Publishing.
About The Optical Society
The Optical Society (OSA) is dedicated to promoting the generation, application, archiving, and dissemination of knowledge in optics and photonics worldwide. Founded in 1916, it is the leading organization for scientists, engineers, business professionals, students, and others interested in the science of light. OSA’s renowned publications, meetings, online resources, and in-person activities fuel discoveries, shape real-life applications and accelerate scientific, technical, and educational achievement.