Published in Physical Review A: Experimental quantum key distribution with simulated ground-to-satellite photon losses and processing limitations

Fundamental laws of quantum physics guarantee the security of encryption keys generated through quantum key distribution, in contrast to standard encryption techniques which rely on assumptions about an eavesdropper's computational ability. That said, special technology is necessary to facilitate quantum key distribution transmissions between parties that are more than a couple of hundred kilometers apart.

A near-term solution is to use an orbiting satellite as a trusted quantum receiver. Here we detail specifically chosen algorithms that make up an implementation of quantum key distribution, suitable for a satellite receiver platform. We examine these algorithms' computational requirements while demonstrating them experimentally as we emulate the variable channel losses that would be experienced during a satellite pass (following those we published about previously).

J.-P. Bourgoin, N. Gigov, B. L. Higgins, Z. Yan, E. Meyer-Scott, A. K. Khandani, N. Lütkenhaus, and T. Jennewein

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Hey look-it, I'm on the TV!

So it seems my face has now graced (or disgraced, perhaps) North American television. Some folks from DMG Productions were in the lab a while ago gathering footage for a segment on IQC for Innovations with Ed Begley, Jr. Though my supervisor fielded the actual spoken material, you can spot me in the background of various “action shots” discussing clearly very important things™ with students and colleagues.

Here's the segment in question, first broadcast on Discovery Channel, May 25, 2015.

I've similarly been on Australian TV before, so that makes two continents that have had to deal with my mug on air.

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Published in Journal of Lightwave Technology: Novel high-speed polarization source for decoy-state BB84 quantum key distribution over free space and satellite links

Here we detail our work on optoelectronics implementing a high-speed high-fidelity source of optical quantum states for quantum encryption.

Z. Yan, E. Meyer-Scott, J.-P. Bourgoin, B. L. Higgins, N. Gigov, A. MacDonald, H. Hübel, and T. Jennewein
J. Lightwave Tech. 31, 1399–408 (2013)

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Published in New Journal of Physics: A comprehensive design and performance analysis of low Earth orbit satellite quantum communication

We perform a thorough theoretical analysis of the expected key rate, success of Bell test, and teleportation distance of experiments performed between the ground and a satellite in low Earth orbit. Our findings demonstrate that successful, regularly repeatable demonstrations are feasible with current technologies and relatively small telescopes.

J.-P. Bourgoin, E. Meyer-Scott, B. L. Higgins, B. Helou, C. Erven, H. Hübel, B. Kumar, D. Hudson, I. D'Souza, R. Girard, R. Laflamme, and T. Jennewein
New J. Phys. 15, 023006 (2013)

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Published in Classical and Quantum Gravity: Fundamental quantum optics experiments conceivable with satellites

An ensemble cast detail the new physics that could be explored by taking quantum optics experiments into space. My first publication as part of Prof. Thomas Jennewein's group, I contributed details about near-term tests and our present work at the Institute for Quantum Computing, and helped out with logistics and proofing.

D. Rideout, T. Jennewein, G. Amelino-Camelia, T. F. Demarie, B. L. Higgins, A. Kempf, A. Kent, R. Laflamme, X. Ma, R. B. Mann, E. Martin-Martinez, N. C. Menicucci, J. Moffat, C. Simon, R. Sorkin, L. Smolin, and D. R. Terno
Class. Quantum Grav. 29, 224011 (2012)

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