Cooling toolbox for atoms in optical lattices

Barnett R Petrov D Lukin M Demler E; Cirac J I; Garcia-Ripoll J J; Gerbier F Widera A Fölling S Mandel O Gericke T Bloch I; Gericke T Gerbier F Widera A Fölling S Mandel O Bloch I; J I Cirac; J-J Garcia-Ripoll; K G H Vollbrecht; Katzgraber H G Esposito A Troyer M; Köhl M; M Popp; Micheli A Brennen G K Zoller P; Popp M Vollbrecht K G Garcia-Ripoll J J Cirac J I; Ryu C Du X Yesilada E Dudarev A M Wan S Niu Q Heinzen D J; Sebby-Strabley J Anderlini M Jessen P S Porto J V

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Cooling toolbox for atoms in optical lattices

Authors: Barnett R Petrov D Lukin M Demler E
Cirac J I
Garcia-Ripoll J J
Gerbier F Widera A Fölling S Mandel O Gericke T Bloch I
Gericke T Gerbier F Widera A Fölling S Mandel O Bloch I
J I Cirac
J-J Garcia-Ripoll
K G H Vollbrecht
Katzgraber H G Esposito A Troyer M
Köhl M
M Popp
Micheli A Brennen G K Zoller P
Popp M Vollbrecht K G Garcia-Ripoll J J Cirac J I
Ryu C Du X Yesilada E Dudarev A M Wan S Niu Q Heinzen D J
Sebby-Strabley J Anderlini M Jessen P S Porto J V
Publication date: 1 January 2006
Publisher: 'IOP Publishing'
Doi

Abstract

We propose and analyze several schemes for cooling bosonic and fermionic atoms in an optical lattice potential close to the ground state of the no-tunnelling regime. Some of the protocols rely on the concept of algorithmic cooling, which combines occupation number filtering with ideas from ensemble quantum computation. We also design algorithms that create an ensemble of defect-free quantum registers. We study the efficiency of our protocols for realistic temperatures and in the presence of a harmonic confinement. We also propose an incoherent physical implementation of filtering which can be operated in a continuous way.Comment: 14 pages, 13 figure

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