Slowing and cooling molecules and neutral atoms by time-varying electric
  field gradients

A. Cable; A. Clairon; A. Lübbert; A. Salop; B. Friedrich; B. Ghaffari; B. P. Anderson; C. Monroe; C. R. Ekstrom; D. Auerbach; D. Herschbach; D. Kakati; D. Kakati; D. P. Katz; D. R. Miller; E. A. Cornell; E. O. Lawrence; E. O. Lawrence; E. S. Chang; E. Tiesinga; G. A. Ising; H. Bethe; H. Gould; H. K. Hughes; H. Pauly; H. von Busch; Harvey Gould; J. D. Weinstein; J. D. Weinstein; J. D. Weinstein; J. Denschlag; J. M. Doyle; Jason A. Maddi; K. D. Bonin; K. D. Bonin; K. Gibble; K. Lindquist; K. von Meyenn; L. Mattera; M. D. Morse; M. Kasevich; N. F. Ramsey; R. E. Miller; R. Marrus; R. N. Zare; R. W. Fox; R. W. Molof; R. Wideröe; S. K. Sekatskii; S. K. Sekatskii; T. Breeden; T. F. Gallagher; T. M. Miller; T. Seideman; T. Seideman; T. Takekoshi; T. W. Ducas; Timothy P. Dinneen; U. Valbusa; V. A. Cho; W. D. Knight; W. G. Kaenders; W. H. Wing

research

Slowing and cooling molecules and neutral atoms by time-varying electric field gradients

Abstract

A method of slowing, accelerating, cooling, and bunching molecules and neutral atoms using time-varying electric field gradients is demonstrated with cesium atoms in a fountain. The effects are measured and found to be in agreement with calculation. Time-varying electric field gradient slowing and cooling is applicable to atoms that have large dipole polarizabilities, including atoms that are not amenable to laser slowing and cooling, to Rydberg atoms, and to molecules, especially polar molecules with large electric dipole moments. The possible applications of this method include slowing and cooling thermal beams of atoms and molecules, launching cold atoms from a trap into a fountain, and measuring atomic dipole polarizabilities.Comment: 13 pages, 10 figures. Scheduled for publication in Nov. 1 Phys. Rev.

Similar works

Full text

Open in the Core reader

Download PDF

Available Versions

Crossref

info:doi/10.1103%2Fphysreva.60...

Last time updated on 30/01/2019