Related papers: On-chip distribution of quantum information using traveling phonons

On-chip distribution of quantum information using traveling phonons

URL: http://arxiv.org/abs/2204.05066v2
Date: Fri, 25 Nov 2022 10:55:06 GMT
Title: On-chip distribution of quantum information using traveling phonons
Authors: Amirparsa Zivari, Niccol\`o Fiaschi, Roel Burgwal, Ewold Verhagen, Robert Stockill, Simon Gr\"oblacher
Abstract summary: We experimentally demonstrate the feasibility of distributing quantum information using phonons. We show how the phononic, together with a photonic qubit, can be used to violate a Bell-type inequality.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Distributing quantum entanglement on a chip is a crucial step towards realizing scalable quantum processors. Using traveling phonons - quantized guided mechanical wavepackets - as a medium to transmit quantum states is currently gaining significant attention, due to their small size and low propagation speed compared to other carriers, such as electrons or photons. Moreover, phonons are highly promising candidates to connect heterogeneous quantum systems on a chip, such as microwave and optical photons for long-distance transmission of quantum states via optical fibers. Here, we experimentally demonstrate the feasibility of distributing quantum information using phonons, by realizing quantum entanglement between two traveling phonons and creating a time-bin encoded traveling phononic qubit. The mechanical quantum state is generated in an optomechanical cavity and then launched into a phononic waveguide in which it propagates for around two hundred micrometers. We further show how the phononic, together with a photonic qubit, can be used to violate a Bell-type inequality.

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