IMEC Collaborates With NUS On Quantum Communication Networks

Today, imec and the National University of Singapore (NUS) announced the signing of a research collaboration agreement to develop chip-based prototypes for secure quantum communication networks.

Securing ourselves through quantum cryptography in a post-quantum world. Dr Charles Lim (left) of NUS and Joris Van Campenhout of imec.

Securing ourselves through quantum cryptography in a post-quantum world. Dr Charles Lim (left) of NUS and Joris Van Campenhout of imec.

In the frame of this five-year agreement, imec and NUS will jointly develop scalable, robust and efficient technologies for quantum key distribution and quantum random number generation, which are amongst the basic building blocks of a truly secure Quantum Internet.

Imec is a world-leading research and innovation hub in nanoelectronics and digital technologies; while NUS is a world-renowned university in Singapore with a global approach to education, research and entrepreneurship, and a focus on Asian perspectives and expertise.

The collaboration between imec and NUS aims to develop scalable, robust, and cost-effective quantum cryptographic systems secure against quantum-based threats.

More details below from the press release.

Imec and NUS to collaborate on chip-based quantum cryptography technology

LEUVEN (Belgium), September 13, 2019 — Research in quantum information science has indicated that large-scale quantum computers (when realised) will render most of today’s encryption techniques insecure.

“Our approach consists of developing and integrating all QKD key components in a single silicon-photonics based chip, which ensures a cost-effective solution. As a first deliverable, we will jointly develop an ultrafast quantum random number generation (QRNG) chip, a key component for generating the secret keys. Secondly, we will work on a compact, fully-integrated photonic quantum transmitter prototype chip. In these efforts, we will strongly leverage imec’s deep expertise in silicon photonics technology, originally developed for conventional datacom and telecom applications,” says Joris Van Campenhout, R&D Program director at imec.

Although one might argue that such a large-scale quantum computer is still some time away, the situation is nevertheless an urgent one.

To that end, two broad directions have been pursued globally, namely a software-based approach called post-quantum cryptography and a hardware-based approach called quantum cryptography.

Post-quantum cryptography is essentially about updating existing cryptographic algorithms and standards so that current infrastructures would be ready for a post-quantum digital world.

It however maintains a security profile that is still based on unproven assumptions.

Quantum cryptography, on the other hand, offers a much stronger security guarantee: its security is solely based on the laws of quantum physics and thus is in principle unbreakable.

Hence, with regards to critical information infrastructures with long-term security needs such as healthcare, government and banking, quantum cryptography is the safer way to go.

“The development of chip-based prototypes will allow us to turn today’s QKD technologies into an efficient communication networking solution. Our team at NUS will bring in expertise on the theory, protocol design, and proof-of-concept experiments of the quantum random number generator and QKD systems. We’re very excited to collaborate with Imec, as their expertise will allow us to translate these solutions into real silicon-photonics based chips – by using imec’s process design kits and re-usable IP blocks,” says Dr. Charles Lim, Assistant Professor at NUS said.

With this approach, two essential building blocks are quantum key distribution (QKD) and quantum random number generation (QRNG). At present, however, the methods and processes enabling these quantum technologies are limiting and expensive.

Consequently, these bottlenecks have made quantum cryptography unattractive for wide-spread deployment.

Together, imec and NUS aim to resolve some of these bottlenecks, leveraging on the theoretical, experimental and engineering expertise of the respective R&D teams.

The overarching objective is to move QKD and QRNG technologies to a platform which is much more scalable, robust, and cost-effective. The research collaboration is supported by the National Research Foundation Singapore under the Quantum Engineering Programme.

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