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Deterministic Generation of a Cluster State of Entangled Photons

We use semiconductor quantum dots, "artificial atoms," to implement a scheme for deterministic generation of long strings of entangled photons in a cluster state, an important resource for quantum information processing. We demonstrate a prototype device which produces strings of a few hundred photons in which the entanglement persists over 5 sequential photons. The implementation follows a proposal by Lindner and Rudolph (Phys. Rev. Lett. 2009) which suggested periodic timed excitation of a precessing electron spin as a mechanism for entangling the electron spin with the polarization of the sequentially emitted photons. In our realization, the entangling qubit is a quantum dot confined dark exciton. By performing full quantum process tomography, we obtain the process map which fully characterizes the evolution of the system, containing the dark exciton and n photons after n applications of the periodic excitations. Our implementation may greatly reduce the resources needed for quantum information processing.

preprint2016arXivOpen access
Ido SchwartzDan CoganEmma R. SchmidgallYaroslav DonLiron GantzOded KennethNetanel H. LindnerDavid Gershoni
quant-ph
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Ido SchwartzDan CoganEmma R. SchmidgallYaroslav DonLiron GantzOded KennethNetanel H. LindnerDavid Gershoni

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