Trapping and cooling particles using a moving atom diode and an atomic mirror

The submission of new items to CORA is currently unavailable due to a repository upgrade. For further information, please contact cora@ucc.ie. Thank you for your understanding.

Files in this item

Icon
Name: Trapping and cooling ...
Size: 2.014Mb
Format: PDF
Description: Published Version
View/Open

Trapping and cooling particles using a moving atom diode and an atomic mirror

Dowdall, Tom; Ruschhaupt, Andreas
Date: 2018
Copyright: © 2018, American Physical Society. All rights reserved.
Related: https://journals.aps.org/pra/abstract/10.1103/PhysRevA.97.013412
Citation: Dowdall, T. and Ruschhaupt, A. (2018) 'Trapping and cooling particles using a moving atom diode and an atomic mirror', Physical Review A, 97(1), 013412 (7pp). doi:10.1103/PhysRevA.97.013412
Published Version: 10.1103/PhysRevA.97.013412

Abstract:

We propose a theoretical scheme for atomic cooling, i.e., the compression of both velocity and position distribution of particles in motion. This is achieved by collisions of the particles with a combination of a moving atomic mirror and a moving atom diode. An atom diode is a unidirectional barrier, i.e., an optical device through which an atom can pass in one direction only. We show that the efficiency of the scheme depends on the trajectory of the diode and the mirror. We examine both the classical and quantum mechanical descriptions of the scheme, along with the numerical simulations to show the efficiency in each case.

Show full item record

This item appears in the following Collection(s)

This website uses cookies. By using this website, you consent to the use of cookies in accordance with the UCC Privacy and Cookies Statement. For more information about cookies and how you can disable them, visit our Privacy and Cookies statement