Physical Review X (Nov 2012)

Cooling a Single Atom in an Optical Tweezer to Its Quantum Ground State

  • A. M. Kaufman,
  • B. J. Lester,
  • C. A. Regal

DOI
https://doi.org/10.1103/PhysRevX.2.041014
Journal volume & issue
Vol. 2, no. 4
p. 041014

Abstract

Read online Read online

We report cooling of a single neutral atom to its three-dimensional vibrational ground state in an optical tweezer. After employing Raman sideband cooling for tens of milliseconds, we measure via sideband spectroscopy a three-dimensional ground-state occupation of about 90%. We further observe coherent control of the spin and motional state of the trapped atom. Our demonstration shows that an optical tweezer, formed simply by a tightly focused beam of light, creates sufficient confinement for efficient sideband cooling. This source of ground-state neutral atoms will be instrumental in numerous quantum simulation and logic applications that require a versatile platform for storing and manipulating ultracold single neutral atoms. For example, these results will improve current optical-tweezer experiments studying atom-photon coupling and Rydberg quantum logic gates, and could provide new opportunities such as rapid production of single dipolar molecules or quantum simulation in tweezer arrays.