Damagnetization cooling of a gas

A Griesmaier; A Kastler; A. Griesmaier; AH Morrish; AJ Kerman; AS Oja; B Friedrich; C Cohen-Tannoudji; CI Hancox; DJ Han; HJ Lee; J. Stuhler; JI Cirac; JI Cirac; JJ McClelland; JT Touriniemi; M Olshanii; M. Fattori; N Kurti; OV Lounasmaa; S Hensler; S Hensler; S Wolf; S. Goetz; S. Hensler; T. Koch; T. Pfau; TW Hijmans; TW Hänsch; VK Pecharsky; WJ De Haas; Y Castin

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Damagnetization cooling of a gas

Authors: A Griesmaier
A Kastler
A. Griesmaier
AH Morrish
AJ Kerman
AS Oja
B Friedrich
C Cohen-Tannoudji
CI Hancox
DJ Han
HJ Lee
J. Stuhler
JI Cirac
JI Cirac
JJ McClelland
JT Touriniemi
M Olshanii
M. Fattori
N Kurti
OV Lounasmaa
S Hensler
S Hensler
S Wolf
S. Goetz
S. Hensler
T. Koch
T. Pfau
TW Hijmans
TW Hänsch
VK Pecharsky
WJ De Haas
Y Castin
Publication date: 18 October 2006
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

We demonstrate demagnetization cooling of a gas of ultracold

^{52}

Cr atoms. Demagnetization is driven by inelastic dipolar collisions which couple the motional degrees of freedom to the spin degree. By that kinetic energy is converted into magnetic work with a consequent temperature reduction of the gas. Optical pumping is used to magnetize the system and drive continuous demagnetization cooling. Applying this technique, we can increase the phase space density of our sample by one order of magnitude, with nearly no atom loss. This method can be in principle extended to every dipolar system and could be used to achieve quantum degeneracy via optical means.Comment: 10 pages, 5 figure

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