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Main Authors: Phatak, Saumitra S., Blodgett, Karl N., Peana, David, Chen, Meng Raymond, Hood, Jonathan D.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.19153
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author Phatak, Saumitra S.
Blodgett, Karl N.
Peana, David
Chen, Meng Raymond
Hood, Jonathan D.
author_facet Phatak, Saumitra S.
Blodgett, Karl N.
Peana, David
Chen, Meng Raymond
Hood, Jonathan D.
contents Cooling atoms to the ground-state of optical tweezers is becoming increasingly important for high-fidelity imaging, cooling, and molecular assembly. While extensive theoretical work has been conducted on cooling in free space, fewer studies have focused on cooling in bound states. In this work, we present a unified formalism for optical cooling mechanisms in neutral atom tweezers, including resolved and unresolved sideband cooling with different trapping potentials, polarization gradient cooling, gray molasses cooling, $Λ$-enhanced gray molasses cooling, and Raman sideband cooling. We perform simulations and demonstrate good agreement with a simplified spin model. We derive and discuss the fundamental limits of each cooling mechanism and propose new strategies for achieving ground-state cooling in optical tweezers. Our findings provide valuable insights into optimizing cooling schemes for neutral atoms in optical tweezers, paving the way for minimizing thermal decoherence in Rydberg and molecular gates and improving efficiencies of molecular assembly.
format Preprint
id arxiv_https___arxiv_org_abs_2406_19153
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Generalized Theory for Optical Cooling of a Trapped Atom with Spin
Phatak, Saumitra S.
Blodgett, Karl N.
Peana, David
Chen, Meng Raymond
Hood, Jonathan D.
Atomic Physics
Quantum Physics
Cooling atoms to the ground-state of optical tweezers is becoming increasingly important for high-fidelity imaging, cooling, and molecular assembly. While extensive theoretical work has been conducted on cooling in free space, fewer studies have focused on cooling in bound states. In this work, we present a unified formalism for optical cooling mechanisms in neutral atom tweezers, including resolved and unresolved sideband cooling with different trapping potentials, polarization gradient cooling, gray molasses cooling, $Λ$-enhanced gray molasses cooling, and Raman sideband cooling. We perform simulations and demonstrate good agreement with a simplified spin model. We derive and discuss the fundamental limits of each cooling mechanism and propose new strategies for achieving ground-state cooling in optical tweezers. Our findings provide valuable insights into optimizing cooling schemes for neutral atoms in optical tweezers, paving the way for minimizing thermal decoherence in Rydberg and molecular gates and improving efficiencies of molecular assembly.
title A Generalized Theory for Optical Cooling of a Trapped Atom with Spin
topic Atomic Physics
Quantum Physics
url https://arxiv.org/abs/2406.19153