A photon–photon quantum gate based on a single atom in an optical resonator

That two photons pass each other undisturbed in free space is ideal for the faithful transmission of information, but prohibits an interaction between the photons. Such an interaction is, however, required for a plethora of applications in optical quantum information processing. The long-standing challenge here is to realize a deterministic photon–photon gate, that is, a mutually controlled logic operation on the quantum states of the photons. This requires an interaction so strong that each of the two photons can shift the other’s phase by π radians. For polarization qubits, this amounts to the conditional flipping of one photon’s polarization to an orthogonal state. So far, only probabilistic gates based on linear optics and photon detectors have been realized, because “no known or foreseen material has an optical nonlinearity strong enough to implement this conditional phase shift”. Meanwhile, tremendous progress in the development of quantum-nonlinear systems has opened up new possibilities for single-photon experiments. Platforms range from Rydberg blockade in atomic ensembles to single-atom cavity quantum electrodynamics. Applications such as single-photon switches and transistors, two-photon gateways, nondestructive photon detectors, photon routers and nonlinear phase shifters have been demonstrated, but none of them with the ideal information carriers: optical qubits in discriminable modes. Here we use the strong light–matter coupling provided by a single atom in a high-finesse optical resonator to realize the Duan–Kimble protocol of a universal controlled phase flip (π phase shift) photon–photon quantum gate. We achieve an average gate fidelity of (76.2 ± 3.6) per cent and specifically demonstrate the capability of conditional polarization flipping as well as entanglement generation between independent input photons. This photon–photon quantum gate is a universal quantum logic element, and therefore could perform most existing two-photon operations. The demonstrated feasibility of deterministic protocols for the optical processing of quantum information could lead to new applications in which photons are essential, especially long-distance quantum communication and scalable quantum computing.

[1]  Mahdi Hosseini,et al.  Large conditional single-photon cross-phase modulation , 2015, Proceedings of the National Academy of Sciences.

[2]  G. Rempe,et al.  Frequency splitting of polarization eigenmodes in microscopic Fabry–Perot cavities , 2014, 1408.4367.

[3]  Pedram Khalili Amiri,et al.  Quantum computers , 2003 .

[4]  R Raussendorf,et al.  A one-way quantum computer. , 2001, Physical review letters.

[5]  Andreas Reiserer,et al.  Nondestructive Detection of an Optical Photon , 2013, Science.

[6]  Archil Avaliani,et al.  Quantum Computers , 2004, ArXiv.

[7]  Julio Gea-Banacloche,et al.  Impossibility of large phase shifts via the giant Kerr effect with single-photon wave packets , 2009, 0911.4682.

[8]  Jeffrey H. Shapiro,et al.  Single-photon Kerr nonlinearities do not help quantum computation , 2006 .

[9]  Christian Nölleke,et al.  Ground-state cooling of a single atom at the center of an optical cavity. , 2012, Physical review letters.

[10]  Todd A. Brun,et al.  Quantum Computing , 2011, Computer Science, The Hardware, Software and Heart of It.

[11]  Stephan Dürr,et al.  Optical π phase shift created with a single-photon pulse , 2015, Science Advances.

[12]  Serge Rosenblum,et al.  All-optical routing of single photons by a one-atom switch controlled by a single photon , 2014, Science.

[13]  J. O'Brien Optical Quantum Computing , 2007, Science.

[14]  Christian Junge,et al.  Nonlinear π phase shift for single fibre-guided photons interacting with a single resonator-enhanced atom , 2014, Nature Photonics.

[15]  Norbert Kalb,et al.  A quantum gate between a flying optical photon and a single trapped atom , 2014, Nature.

[16]  Andreas Reiserer,et al.  Cavity-based quantum networks with single atoms and optical photons , 2014, 1412.2889.

[17]  P. Zoller,et al.  Complete Characterization of a Quantum Process: The Two-Bit Quantum Gate , 1996, quant-ph/9611013.

[18]  Pieter Kok,et al.  Introduction to Optical Quantum Information Processing: Preface , 2010 .

[19]  H. Kimble,et al.  Scalable photonic quantum computation through cavity-assisted interactions. , 2004, Physical review letters.

[20]  Hood,et al.  Measurement of conditional phase shifts for quantum logic. , 1995, Physical review letters.

[21]  J. D. Thompson,et al.  Nanophotonic quantum phase switch with a single atom , 2014, Nature.

[22]  H. J. Kimble,et al.  Robust quantum gates on neutral atoms with cavity-assisted photon scattering , 2005 .

[23]  Darrick E. Chang,et al.  Quantum nonlinear optics — photon by photon , 2014, Nature Photonics.

[24]  Two-photon gateway in one-atom cavity quantum electrodynamics , 2009 .

[25]  Wolfgang Dür,et al.  Quantum Repeaters: The Role of Imperfect Local Operations in Quantum Communication , 1998 .

[26]  T. Ralph,et al.  Demonstration of an all-optical quantum controlled-NOT gate , 2003, Nature.

[27]  M. Lukin,et al.  Photon-photon interactions via Rydberg blockade. , 2011, Physical review letters.

[28]  H. Fedder,et al.  Single-photon transistor mediated by interstate Rydberg interactions. , 2014, Physical review letters.

[29]  Katharina Schneider,et al.  Single-photon transistor using a Förster resonance. , 2014, Physical review letters.

[30]  Stephan Dürr,et al.  Single-photon switch based on Rydberg blockade. , 2013, Physical review letters.

[31]  E. Knill,et al.  A scheme for efficient quantum computation with linear optics , 2001, Nature.