CUDOS breakthrough in road to secure technology

3 May 2011

Groundbreaking research in quantum light sources led by CUDOS researchers based within the School of Physics at the University of Sydney will result in information speeds many times faster and data that is almost impossible to hack.

The breakthrough, which uses silicon photonic crystals to slow down light, is a collaboration between CUDOS nodes at the University of Sydney and Macquarie University, along with colleagues at the University of Bristol and the University of St Andrews (UK), and the Ecole Centrale de Lyon in France.

CUDOS researchers have generated individual pairs of photons in the smallest device ever by slowing light down using silicon photonic crystals. At 100 microns long (approximately the thickness of a human hair) CUDOS's quantum photon device is one hundred times smaller than the one-centimetre devices used by other groups.

Dr Chunle Xiong of the University of Sydney, a co-author and Project Leader for the CUDOS program in Quantum Integrated Photonics, says the device's nano-scale means that potentially hundreds of these photon devices can be incorporated into a single chip. This is a key step to building practical quantum technologies that will make communications much more secure and computations many times faster.

"We are able to do this by slowing light down through the use of silicon photonic crystals, which means the ultrashort device behaves as a much longer device, so that the photons are generated in only 100 microns," says Dr Xiong.

Macquarie University's Associate Professor Michael Steel, co-author and CUDOS Chief Investigator, says: "Current systems use classical light to carry information, which hackers can easily tap into and use to their advantage. But you cannot copy the information encoded in quantum states without being noticed by the system. Single photon devices will ensure communication and information systems are secure from hackers, guaranteeing peace of mind for the users."

This pioneering technology will ensure the next generation of information systems is secure and faster, says Professor Ben Eggleton, Director of ARC Centre of Excellence CUDOS and co-author of the paper. The experiment is outlined in a groundbreaking paper to be presented at a prestigious international conference in Baltimore next week for the world's leading researchers in laser and quantum electronics.

Professor Eggleton says this breakthrough is taking CUDOS 'Mark II' into a new and exciting direction. Federal Minister for Innovation, Industry, Science and Research, Senator Kim Carr, officially launched CUDOS II only three weeks ago.

The post-deadline paper, to be presented at the Conference on Lasers and Electro-Optics (CLEO) and the Quantum Electronics Laser Science Conference (QELS) on Thursday 5 May in Baltimore, USA, is titled: "Correlated Photon-Pair Generation in an Ultra-Compact Silicon Photonic Crystal Waveguide" by Christelle Monat 1,2, Alex Clark1,3, Chunle Xiong1, Christian Grillet1, Graham Marshall4, Michael J. Steel4, Juntao Li5, Liam O'Faolain5, Thomas F. Krauss5 and Benjamin J. Eggleton1

1. Centre for Ultrahigh bandwidth Devices for Optical Systems (CUDOS), School of Physics, University of Sydney, NSW 2006, Australia; 2. Institut des Nanotechnologies de Lyon, Ecole Centrale de Lyon, 36 Avenue Guy de Collongue, 69134 Ecully, France; 3. Centre for Quantum Photonics, University of Bristol, Queens Building, University Walk, Bristol, BS8 1TR, UK; 4. CUDOS, Dept of Physics & Astronomy, Macquarie University, NSW 2109, Australia; 5. School of Physics and Astronomy, University of St Andrews, Fife, KY16 9SS, UK

Contact: Alison Muir

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