Christopher Monroe - “Quantum Computing with Trapped Ions”
Stanford University
APPLIED PHYSICS/PHYSICS COLLOQUIUM
The Paul Kirkpatrick Awards will be presented at the start of this colloquium
Tuesday, May 15, 2018
4:30 p.m. on campus in Hewlett Teaching Center, Rm. 201
Christopher Monroe
University of Maryland
“Quantum Computing with Trapped Ions”
Individual atoms are standards for quantum information technology, acting as qubits that have unsurpassed levels of quantum coherence, can be replicated and scaled with the atomic clock accuracy, and allow near-perfect measurement. Atomic ions can be confined by silicon-based chip traps with lithographically-defined electrodes under high vacuum in a room temperature environment. Entangling quantum gate operations can be mediated with control laser beams, allowing the qubit connectivity graph to be reconfigured and optimally adapted to a given algorithm or mode of quantum computing. Existing work has shown 99.9% fidelity gate operations, fully-connected control with up to about 10 qubits, and quantum simulations with over 50 qubits. I will speculate on combining all this into a single universal quantum computing device that can be co-designed with future quantum applications and scaled to useful dimensions.
Видео Christopher Monroe - “Quantum Computing with Trapped Ions” канала Stanford Physics
APPLIED PHYSICS/PHYSICS COLLOQUIUM
The Paul Kirkpatrick Awards will be presented at the start of this colloquium
Tuesday, May 15, 2018
4:30 p.m. on campus in Hewlett Teaching Center, Rm. 201
Christopher Monroe
University of Maryland
“Quantum Computing with Trapped Ions”
Individual atoms are standards for quantum information technology, acting as qubits that have unsurpassed levels of quantum coherence, can be replicated and scaled with the atomic clock accuracy, and allow near-perfect measurement. Atomic ions can be confined by silicon-based chip traps with lithographically-defined electrodes under high vacuum in a room temperature environment. Entangling quantum gate operations can be mediated with control laser beams, allowing the qubit connectivity graph to be reconfigured and optimally adapted to a given algorithm or mode of quantum computing. Existing work has shown 99.9% fidelity gate operations, fully-connected control with up to about 10 qubits, and quantum simulations with over 50 qubits. I will speculate on combining all this into a single universal quantum computing device that can be co-designed with future quantum applications and scaled to useful dimensions.
Видео Christopher Monroe - “Quantum Computing with Trapped Ions” канала Stanford Physics
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