@article{Hinds:1999:18/201,
author = {Hinds, EA and Hughes, IG},
doi = {18/201},
journal = {Journal of Physics D: Applied Physics},
title = {Magnetic atom optics: Mirrors, guides, traps, and chips for atoms},
url = {http://dx.doi.org/10.1088/0022-3727/32/18/201},
volume = {32},
year = {1999}
}

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TY  - JOUR
AB  - For the last decade it has been possible to cool atoms to microkelvin temperatures (approximately 1 cm s-1) using a variety of optical techniques. Light beams provide the very strong frictional forces required to slow atoms from room temperature (approximately 500 m s-1). However, once the atoms are cold, the relatively weak conservative forces of static electric and magnetic fields play an important role. In our group we have been studying the interaction of cold rubidium atoms with periodically magnetized data storage media. Here we review the underlying principles of the forces acting on atoms above a suitably magnetized substrate or near current-carrying wires. We also summarize the status of experiments. These structures can be used as smooth or corrugated reflectors for controlling the trajectories of cold atoms. Alternatively, they may be used to confine atoms to a plane, a line, or a dot and in some cases to reach the quantum limit of confinement. Atoms levitated above a magnetized surface can be guided electrostatically by wires deposited on the surface. The flow and interaction of atoms in such a structure may form the basis of a new technology, `integrated atom optics' which might ultimately be capable of realizing a quantum computer.
AU  - Hinds,EA
AU  - Hughes,IG
DO  - 18/201
PY  - 1999///
SN  - 0022-3727
TI  - Magnetic atom optics: Mirrors, guides, traps, and chips for atoms
T2  - Journal of Physics D: Applied Physics
UR  - http://dx.doi.org/10.1088/0022-3727/32/18/201
VL  - 32
ER  - 

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