Quantum Nano-Photonic Devices Based on Rare-Earth Ions

Monday, October 9, 2017

4:15 pm

Spilker 232 Map

Sponsored by:
The Departments of Applied Physics, Physics, and Ginzton Laboratory

Oct 09, 2017
4:15 PM, Spilker 232
http://campus-map.stanford.edu/index.cfm?ID=04-040 - Map

QUANTUM NANO-PHOTONIC DEVICES BASED ON RARE EARTH IONS

Andrei Faraon
Applied Physics
California Institute of Technology

Quantum light-matter interfaces that reversibly map photonic quantum states onto atomic states are essential components in the quantum engineering toolbox with applications in quantum communication, computing, and quantum-enabled sensing. I present a new platform for on-chip quantum light-matter interfaces based on nanophotonic resonators coupled to rare-earth-ions in crystals. The rare-earth ions exhibit long coherence times on optical transitions, which makes them suitable for optical quantum memories. We demonstrate a high-fidelity nanophotonic quantum memory based on a mesoscopic neodymium ensemble coupled to a photonic crystal cavity. The nanocavity enables >95% spin polarization for efficient initialization of the atomic frequency comb memory, and time-bin-selective readout via enhanced optical Stark shift of the comb frequencies. Our current technology can be readily transferred to erbium doped devices for telecom memories that can be integrated with silicon photonics. Besides ensemble memories, single rare-earth-ions coupled to nano-resonators can be used as single optically-addressable quantum bits where the quantum state is mapped on their Zeeman or hyperfine levels with long coherence time. Our solid-state nano-photonic quantum light-matter interfaces can be integrated with other chip-scale photon source and detector devices for multiplexed quantum and classical information processing at the nodes of quantum networks. I also discuss prospects for integration with superconducting resonators and qubits, which can lead to devices for reversible quantum transduction of optical photons to microwave photons, thus enabling optical interconnects between superconducting quantum computers.

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Dr. Andrei Faraon is an Assistant Professor of Applied Physics at California Institute of Technology. After earning a B.S. degree in physics with honors in 2004 from CalTech he received his M.S. in Electrical Engineering and PhD in Applied Physics both from Stanford University in 2009. At Stanford, Dr. Faraon was involved with seminal experiments on quantum optics using single indium arsenide quantum dots strongly coupled to photonic crystal cavities in gallium arsenide. After earning his PhD, Dr. Faraon spent three years as a postdoc at Hewlett Packard where he was involved with pioneering experiments on diamond quantum photonic devices coupled to solid-state spins. He demonstrated the first nano-resonators coupled to single nitrogen vacancy centers in mono-crystalline diamond.

Faraon left HP in 2012 to become an Assistant Professor at Caltech, where he set up a lab specialized in developing nano-photonic technologies for devices that operate close to the fundamental limit of light-matter interaction. He is focused both on fundamental challenges on how to control the interaction between single atoms and single photons using nano-technologies, and on using nano-photonics to build cutting edge devices for imaging and sensing. He is the recipient of the 2015 NSF CAREER award, the 2015 AFOSR young investigator award, and the 2016 ONR Young Investigator Award.

When:
Monday, October 9, 2017
4:15 pm – 5:15 pm
Where:
Spilker 232 Map
Tags:

Engineering Seminar Science 

Audience:
General Public, Faculty/Staff, Students, Alumni/Friends
Contact:
650-723-0206, ingrid@ee.stanford.edu