Julio T. Barreiro, Tzu-Chieh Wei, Paul G. Kwiat
Published 2010-09-27Version 1
Quantum teleportation faces increasingly demanding requirements for transmitting large or even entangled systems. However, knowledge of the state to be transmitted eases its reconstruction, resulting in a protocol known as remote state preparation. A number of experimental demonstrations to date have been restricted to single-qubit systems. We report the remote preparation of two-qubit "hybrid" entangled states, including a family of vector-polarization beams. Our single-photon states are encoded in the photon spin and orbital angular momentum. We reconstruct the states by spin-orbit state tomography and transverse polarization tomography. The high fidelities achieved for the vector-polarization states opens the door to optimal coupling of down-converted photons to other physical systems, such as an atom, as required for scalable quantum networks, or plasmons in photonic nanostructures.
Comments: Letter: 4 pages, 1 figure. Supplementary material: 1 page
Journal: Phys. Rev. Lett. 105, 030407 (2010)
Derivation and experimental test of fidelity benchmarks for remote preparation of arbitrary qubit states
Remote preparation for single-photon state in two degrees of freedom with hyper-entangled states
Remote Preparation of Mixed States via Noisy Entanglement
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