Loss-tolerant state engineering for quantum-enhanced metrology via the reverse Hong-Ou-Mandel effect
Nature Communications Springer Nature 7:1 (2016) 11925
Abstract:
Highly entangled quantum states, shared by remote parties, are vital for quantum communications and metrology. Particularly promising are the N00N states-entangled N-photon wavepackets delocalized between two different locations-which outperform coherent states in measurement sensitivity. However, these states are notoriously vulnerable to losses, making them difficult to both share them between remote locations and recombine in order to exploit interference effects. Here we address this challenge by utilizing the reverse Hong-Ou-Mandel effect to prepare a high-fidelity two-photon N00N state shared between two parties connected by a lossy optical medium. We measure the prepared state by two-mode homodyne tomography, thereby demonstrating that the enhanced phase sensitivity can be exploited without recombining the two parts of the N00N state. Finally, we demonstrate the application of our method to remotely prepare superpositions of coherent states, known as Schrödinger's cat states.A scheme for quantum teleportation between discrete and continuous encodings of an optical qubit
(2016)
Loss-tolerant quantum enhanced metrology and state engineering via the reverse Hong-Ou-Mandel effect
(2016)
Undoing the effect of loss on quantum entanglement
Nature Photonics Springer Nature 9:11 (2015) 764-768
Complete temporal characterization of a single photon
Light: Science & Applications Springer Nature 4:6 (2015) e298-e298