Kavli Affiliate: Andrei Faraon
| First 5 Authors: Ioana Craiciu, Mi Lei, Jake Rochman, John G. Bartholomew, Andrei Faraon
| Summary:
Quantum networks will enable a variety of applications, from secure
communication and precision measurements to distributed quantum computing.
Storing photonic qubits and controlling their frequency, bandwidth and
retrieval time are important functionalities in future optical quantum
networks. Here we demonstrate these functions using an ensemble of erbium ions
in yttrium orthosilicate coupled to a silicon photonic resonator and controlled
via on-chip electrodes. Light in the telecommunication C-band is stored,
manipulated and retrieved using a dynamic atomic frequency comb protocol
controlled by linear DC Stark shifts of the ion ensemble’s transition
frequencies. We demonstrate memory time control in a digital fashion in
increments of 50 ns, frequency shifting by more than a pulse-width ($pm39$
MHz), and a bandwidth increase by a factor of three, from 6 MHz to 18 MHz.
Using on-chip electrodes, electric fields as high as 3 kV/cm were achieved with
a low applied bias of 5 V, making this an appealing platform for rare earth
ions, which experience Stark shifts of the order of 10 kHz/(V/cm).
| Search Query: ArXiv Query: search_query=au:”Andrei Faraon”&id_list=&start=0&max_results=10