Testing quantum correlations in a confined atomic cloud by scattering
  fast atoms

A. B. Kuklov; A.I. Safonov; A.K. Setty; A.S. Parkins; B. V. Svistunov; C.C. Bradley; C.N. Yang; D.G. Fried; D.O. Edwards; E.A. Burt; E.W. Hagley; H. Steck; J. Stenger; K.B. Davis; L. Deng; M.H. Anderson; M.R. Andrews; P.C. Hohenberg; P.E. Sokol; V.U. Nayak; W. Kohn; Y. Castin; Yu. Kagan; Yu. Kagan

research

Testing quantum correlations in a confined atomic cloud by scattering fast atoms

Authors: A. B. Kuklov
A.I. Safonov
A.K. Setty
A.S. Parkins
B. V. Svistunov
C.C. Bradley
C.N. Yang
D.G. Fried
D.O. Edwards
E.A. Burt
E.W. Hagley
H. Steck
J. Stenger
K.B. Davis
L. Deng
M.H. Anderson
M.R. Andrews
P.C. Hohenberg
P.E. Sokol
V.U. Nayak
W. Kohn
Y. Castin
Yu. Kagan
Yu. Kagan
Publication date: 1 December 1998
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We suggest measuring one-particle density matrix of a trapped ultracold atomic cloud by scattering fast atoms in a pure momentum state off the cloud. The lowest-order probability of the inelastic process, resulting in a pair of outcoming fast atoms for each incoming one, turns out to be given by a Fourier transform of the density matrix. Accordingly, important information about quantum correlations can be deduced directly from the differential scattering cross-section. A possible design of the atomic detector is also discussed.Comment: 5 RevTex pages, no figures, submitted to PR

Similar works

Full text

Available Versions

Crossref

Last time updated on 02/01/2020