Toshiba Europe Ltd recently announced it has developed the world’s first chip-based quantum key distri­­bution (QKD) system. This advance will enable the mass manufacture of quantum security techno­­logy, bringing its appli­cation to a much wider range of scenarios including to Internet of Things (IoT) solutions. QKD addresses the demand for crypto­­graphy which will remain secure from attack by the super­­computers of tomorrow. In particular, a large-scale quantum computer will be able to effi­ciently solve the difficult mathematical problems that are the basis of the public key crypto­­graphy widely used today for secure communi­­cations and e-commerce. In contrast, the protocols used for quantum crypto­­graphy can be proven secure from first principles and will not be vulnerable to attack by a quantum computer, or indeed any computer in the future.

For quantum crypto­graphy to become as ubiquitous as the algorithmic crypto­graphy we use today, it is important that the size, weight and power consumption are further reduced. This is especially true for extending QKD and quantum random number generators (QRNG) into new domains such as the last-mile connection to the customer or IoT. The develop­ment of chip-based solutions is essential to enabling mass market appli­cations, which will be integral to the realisation of a quantum-ready economy.

Toshiba has developed techniques for shrinking the optical circuits used for QKD and QRNG into tiny semi­conductor chips. These are not only much smaller and lighter than their fibre optic counterparts, but also consume less power. Most signi­ficantly, many can be fabricated in parallel on the same semi­conductor wafer using standard techniques used within the semi­conductor industry, allowing them to be manufactured in much larger numbers. For example, the quantum transmitter chips developed by Toshiba measure just 2 x 6 milli­meters, allowing several hundred chips to be produced simul­taneously on a wafer. 

Andrew Shields, Head of Quantum Techno­logy at Toshiba Europe, remarked, “Photonic integration will allow us to manu­facture quantum security devices in volume in a highly repeatable fashion. It will enable the production of quantum products in a smaller form factor, and subse­quently allow the roll out of QKD into a larger fraction of the telecom and datacom network.” Taro Shimada, Chief Digital Officer of Toshiba Cor­poration comments, “Toshiba has invested in quantum techno­logy R&D in the UK for over two decades. This latest advancement is highly significant, as it will allow us to manufacture and deliver QKD in much larger quantities. It is an important milestone towards our vision of building a platform for quantum-safe communi­cations based upon ubiquitous quantum security devices.” 

QKD systems typically comprise a complex fiber-optic circuit, inte­grating discrete components, such as lasers, electro-optic modulators, beam-splitters and fibre couplers. As these components are relatively bulky and expensive, the purpose of this work was to develop a QKD system in which the fibre-optic circuit and devices are written in milli­meter scale semi­conductor chips. In the first complete QKD prototype quantum photonic chips of different functionality are deployed. Random bits for preparing and measuring the qubits are produced in quantum random number generator (QRNG) chips and converted in real-time into high-speed modulation patterns for the chip-based QKD trans­mitter (QTx) and receiver (QRx) using field-programmable gate arrays (FPGAs). 

Photons are detected using fast-gated single photon detectors. Sifting, photon statistics evaluation, time synchroni­zation and phase stabili­zation are done via a 10 Gb/s optical link between the FPGA cores, enabling autonomous operation over extended periods of time. As part of the demons­tration, the chip QKD system was interfaced with a commercial encryptor, allowing secure data transfer with a bit rate up to 100 Gb/s. To promote integration into conventional communi­cation infra­structures, the QKD units are assembled in compact 1U rackmount cases. The QRx and QTx chips are packaged into C-form-factor-pluggable-2 (CFP2) modules, a widespread form-factor in coherent optical communi­cations, to ensure forward compa­tibility of the system with successive QKD chip generations, making it easily upgradeable. Off-the-shelf 10 Gb/s small-form-factor pluggable (SFP) modules are used for the public communi­cation channels.

Researcher Taofiq Paraiso says: “We are witnessing with photonic integrated circuits a similar revolution to that which occurred with electronic circuits. PICs are conti­nuously serving more and more diverse applications. Of course, the requirements for quantum PICs are more stringent than for conventional appli­cations, but this work shows that a fully deployable chip-based QKD system is now attainable, marking the end of an important challenge for quantum techno­logies. This opens a wide-range of perspectives for the deployment of compact, plug-and-play quantum devices that will certainly strongly impact our society.”

The QKD market is expected to grow to approxi­mately $20 billion worldwide in 2035. Large quantum-secured fibre networks are currently under construction in Europe and South-East Asia, and there are plans to launch satellites that can extend the networks to a global scale. In October 2020, Toshiba released two products for fiber-based QKD, which are based on discrete optical components. Together with project partners, Toshiba has implemented quantum-secured metro networks and long-distance fibre optic backbone links in the UK, Europe, US and Japan. (Source: Toshiba)

Reference: T. K. Paraïso et al.: A photonic integrated quantum secure communication system, Nat. Phot. 15, 850 (2021); DOI: 10.1038/s41566-021-00873-0

Link: Cambridge Research Laboratory, Toshiba Europe Ltd, Cambridge, UK