Scalable local addressing of atomic qubits using integrated photonics
ORAL
Abstract
Quantum computers based on neutral-atom qubits have emerged as promising architectures for scalable quantum computing. As the number of qubits and circuit depth grow, these optically addressed systems demand scalable and precise control solutions across multiple independent degrees of freedom in the addressing field. Here, we demonstrate a local addressing system for neutral-atom quantum computers using integrated photonics. Our multi-channel photonic integrated circuit (PIC) features high-power, high-speed switching with high extinction ratios across the visible to near-infrared spectrum. We describe our atomic-photonic integration approach and discuss the scale-up of photonic control for large-scale quantum systems.
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Presenters
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Robert J DeAngelo
QuEra Computing Inc.
Authors
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Noel Wan
QuEra Computing Inc.
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Mengdi Zhao
QuEra Computing Inc.
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Anshuman Singh
QuEra Computing Inc.
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Robert J DeAngelo
QuEra Computing Inc.
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Henry Thoreen
QuEra Computing Inc.
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Manuj Singh
QuEra Computing Inc.
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Daniel Dominguez
Sandia National Laboratories
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Andrew Leenheer
Sandia National Laboratories
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Ramon Szmuk
Q.M Technologies Ltd. (Quantum Machines)
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Yoav Romach
Q.M Technologies Ltd. (Quantum Machines)
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Yonatan Cohen
Q.M Technologies Ltd. (Quantum Machines)
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Matt Eichenfield
Sandia National Laboratories
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Dirk R Englund
Columbia University, Massachusetts Institute of Technology, MIT
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Nathan Gemelke
QuEra Computing Inc.