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Quantum Computation and Quantum Simulation with Ultracold Molecules

Physics

Quantum Computation and Quantum Simulation with Ultracold Molecules

S. L. Cornish, M. R. Tarbutt, et al.

Explore the mesmerizing world of ultracold molecules, which hold immense promise for advancing quantum information processing and simulation. Researchers Simon L. Cornish, Michael R. Tarbutt, and Kaden R. A. Hazzard delve into the breakthroughs and ongoing challenges in harnessing these fascinating entities to unlock their full potential.

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~3 min • Beginner • English
Abstract
Ultracold molecules confined in optical lattices or tweezer traps can be used to process quantum information and simulate the behaviour of many-body quantum systems. Molecules offer several advantages for these applications. They have a large set of stable states with strong transitions between them and long coherence times. They can be prepared in a chosen state with high fidelity, and the state populations can be measured efficiently. They have controllable long-range dipole-dipole interactions that can be used to entangle pairs of molecules and generate interesting many-body states. We review the advances that have been made and the challenges still to overcome, and describe the new ideas that will unlock the full potential of the field.
Publisher
Nature Physics
Published On
Jan 10, 2024
Authors
Simon L. Cornish, Michael R. Tarbutt, Kaden R. A. Hazzard
DOI
https://doi.org/https://doi.org/10.1038/s41567-024-02453-9
Tags
ultracold molecules
quantum information processing
quantum simulation
dipole-dipole interactions
coherence times

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