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Optical dipole traps for neutral atoms

3 Pith papers cite this work. Polarity classification is still indexing.

3 Pith papers citing it
abstract

The subject of this review are atom traps based on optical dipole forces in laser fields, along with their unique features as storage devices at ultralow energies. The basic physics of the dipole interaction is discussed, and the experimental background of dipole trapping experiments is explained. Specific trapping schemes and experiments are presented, where the wide range of applications of dipole traps is explored considering particular examples.

fields

quant-ph 3

years

2026 3

verdicts

UNVERDICTED 3

representative citing papers

Quantum-enabled active matter at the atomic scale

quant-ph · 2026-06-23 · unverdicted · novelty 7.0

Cs-133 atoms become active by converting quantum spin-exchange energy from a Rb-87 bath into kinetic motion, quantitatively matched by a parameter-free Langevin model derived from kinetic theory.

Energetics of Rydberg-atom Quantum Computing

quant-ph · 2026-01-06 · unverdicted · novelty 4.0

Provides component-wise energy estimates for Rydberg quantum computers and reports a potential energy advantage over classical DFT execution for the Quantum Fourier Transform under ideal error-free conditions.

citing papers explorer

Showing 3 of 3 citing papers.

  • State-dependent Gaussian gate set using an optical tweezer for trapped ions quant-ph · 2026-06-30 · unverdicted · none · ref 19 · internal anchor

    An optical tweezer implements state-dependent displacement, squeezing, rotation, and beamsplitter gates on the motional modes of trapped 40Ca+ ions.

  • Quantum-enabled active matter at the atomic scale quant-ph · 2026-06-23 · unverdicted · none · ref 69 · internal anchor

    Cs-133 atoms become active by converting quantum spin-exchange energy from a Rb-87 bath into kinetic motion, quantitatively matched by a parameter-free Langevin model derived from kinetic theory.

  • Energetics of Rydberg-atom Quantum Computing quant-ph · 2026-01-06 · unverdicted · none · ref 32 · internal anchor

    Provides component-wise energy estimates for Rydberg quantum computers and reports a potential energy advantage over classical DFT execution for the Quantum Fourier Transform under ideal error-free conditions.