We experimentally demonstrate a variation on a Sisyphus cooling technique
that was proposed for cooling antihydrogen. In our implementation, atoms are
selectively excited to an electronic state whose energy is spatially modulated
by an optical lattice, and the ensuing spontaneous decay completes one Sisyphus
cooling cycle. We characterize the cooling efficiency of this technique on a
continuous beam of Sr, and compare it with radiation pressure based laser
cooling. We demonstrate that this technique provides similar atom number for
lower end temperatures, provides additional cooling per scattering event and is
compatible with other laser cooling methods. This method can be instrumental in
bringing new exotic species and molecules to the ultracold regime.Comment: 11 pages, 11 figure

Bennetts, Shayne

Chen, Chun-Chia

Escudero, Rodrigo González

Pasquiou, Benjamin

Schreck, Florian

English

arXiv

Chen, C.-C.

Bennetts, S.

González Escudero, R.

Schreck, F.

Pasquiou, B.

International Migration, Integration and Social Cohesion online publications

Sisyphus optical lattice decelerator

Leading tests of the Standard Model, like measurements of the electron electric dipole moment or of matter-antimatter asymmetry, are built upon our ability to laser-cool atoms and molecules to ultracold temperatures. Unfortunately, laser-cooling remains limited to a minute collection of species with very specific electronic structures. To include more species, such as polyatomic molecules or exotic atoms like antihydrogen, new cooling methods are needed. Here we demonstrate a method based on Sisyphus cooling that was proposed for laser-cooling antihydrogen. In our implementation, atoms are selectively excited to an electronic state whose energy is spatially modulated by an optical lattice, and the ensuing spontaneous decay completes one Sisyphus cycle. We show that this method eliminates many constraints of traditional radiation-pressure-based approaches, while providing similar atom numbers with lower temperatures. This laser-cooling method can be instrumental in bringing new exotic species and molecules to the ultracold regime.</p

UvA-DARE

Leading tests of the Standard Model, like measurements of the electron electric dipole moment or of matter-antimatter asymmetry, are built upon our ability to laser-cool atoms and molecules to ultracold temperatures. Unfortunately, laser-cooling remains limited to a minute collection of species with very specific electronic structures. To include more species, such as polyatomic molecules or exotic atoms like antihydrogen, new cooling methods are needed. Here we demonstrate a method based on Sisyphus cooling that was proposed for laser-cooling antihydrogen. In our implementation, atoms are selectively excited to an electronic state whose energy is spatially modulated by an optical lattice, and the ensuing spontaneous decay completes one Sisyphus cycle. We show that this method eliminates many constraints of traditional radiation-pressure-based approaches, while providing similar atom numbers with lower temperatures. This laser-cooling method can be instrumental in bringing new exotic species and molecules to the ultracold regime

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Sisyphus Optical Lattice Decelerator

Sisyphus Optical Lattice Decelerator

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International Migration, Integration and Social Cohesion online publications

UvA-DARE

NARCIS

International Migration, Integration and Social Cohesion online publications

International Migration, Integration and Social Cohesion online publications