Title :
Entanglement-Preserving Photonic Switching: Full Cross-Bar Operation With Quantum Data Streams
Author :
Oza, N.N. ; Yu-Ping Huang ; Kumar, Pranaw
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Northwestern Univ., Evanston, IL, USA
Abstract :
As the field of quantum communications matures and adopts larger network topologies, it will require switches capable of multiplexing and demultiplexing entangled photons between network nodes. Such switches will need to operate at high speeds, with low loss, and minimal signal-band noise, while also retaining the quantum state of the routed photons. We present an all-optical, fiber-based, dual-in, dual-out switch that has a switching window of 45 ps and an insertion loss of <;3.0 dB. In addition, the switch introduces minimal degradation to the quantum state of the routed entangled photons. As a test of the switch´s utility, we demultiplex a single quantum channel from a 6.5-GHz dual-channel quantum data stream. The recovered quantum state exhibits a fidelity of 96.2%±1.2% with the prepared state.
Keywords :
multiplexing; optical fibre communication; optical fibre losses; optical fibre testing; optical switches; photonic switching systems; quantum communication; quantum entanglement; quantum optics; all-optical switch; dual-channel quantum data stream; dual-in switch; dual-out switch; entangled photon demultiplexing; entangled photon multiplexing; entanglement-preserving photonic switching; fiber-based switch; fidelity; frequency 6.5 GHz; full cross-bar operation; high speed switches; low loss switches; minimal degradation; minimal signal-band noise; network nodes; network topologies; quantum communications; recovered quantum state; routed entangled photons; routed photon quantum state; single quantum channel; switch utility test; switching window; time 45 ps; Mirrors; Modulation; Multiplexing; Optical switches; Photonics; Quantum entanglement; Quantum communications; cross-phase modulation; nonlinear optical loop mirror; optical fiber communication; optical switches;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2013.2293953
