Litcius/Paper detail

Scalable spin–photon entanglement by time-to-polarization conversion

Rui Vasconcelos, Sarah Reisenbauer, C. L. Salter, Georg Wachter, Daniel Wirtitsch, Jörg Schmiedmayer, Philip Walther, Michael Trupke

2020npj Quantum Information40 citationsDOIOpen Access PDF

Abstract

Abstract The realization of quantum networks and quantum computers relies on the scalable generation of entanglement, for which spin-photon interfaces are strong candidates. Current proposals to produce entangled-photon states with such platforms place stringent requirements on the physical properties of the photon emitters, limiting the range and performance of suitable physical systems. We propose a scalable protocol, which significantly reduces the constraints on the emitter. We use only a single optical transition and an asymmetric polarizing interferometer. This device converts the entanglement from the experimentally robust time basis via a path degree of freedom into a polarization basis, where quantum logic operations can be performed. The fundamental unit of the proposed protocol is realized experimentally in this work, using a nitrogen-vacancy center in diamond. This classically assisted protocol greatly widens the set of physical systems suited for scalable entangled-photon generation and enables performance enhancement of existing platforms.

Topics & Concepts

Quantum entanglementPhotonQuantum sensorPhoton polarizationQuantum networkPhysicsPhoton entanglementQuantum information scienceRealization (probability)PhotonicsScalabilityQuantum computerComputer scienceQuantumOptoelectronicsQuantum mechanicsStatisticsDatabaseMathematicsQuantum Information and CryptographyDiamond and Carbon-based Materials ResearchQuantum optics and atomic interactions