Magnetic trapping of metastable calcium atoms

Hansen, Dirk; Mohr, Janis R.; Hemmerich, Andreas

doi:10.1103/physreva.67.021401

Cited by 26 publications

(18 citation statements)

References 15 publications

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“…5 where we measure temperatures below 25 µK. Similar anomalously low temperatures have been observed in MOT-loaded, magnetically trapped Ca [24] and Sr [25] while unexpectedly high temperatures were reported in Cr [23]. In Ref.…”

Section: Magnetic Trappingsupporting

confidence: 79%

Sub-Doppler laser cooling and magnetic trapping of erbium

2007

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We investigate cooling mechanisms in magneto-optically and magnetically trapped erbium. We find efficient sub-Doppler cooling in our trap, which can persist even in large magnetic fields due to the near degeneracy of two Lande g factors. Furthermore, a continuously loaded magnetic trap is demonstrated where we observe temperatures below 25 microkelvin. These favorable cooling and trapping properties suggest a number of scientific possibilities for rare-earth atomic physics, including narrow linewidth laser cooling and spectroscopy, unique collision studies, and degenerate bosonic and fermionic gases with long-range magnetic dipole coupling

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Section: Magnetic Trappingsupporting

confidence: 79%

Sub-Doppler laser cooling and magnetic trapping of erbium

2007

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“…Double structures were previously reported for Rb [30], Dy [21] and Ca [31] MOTs. The specific cloud density profile in the Rb MOT was caused by a bi-harmonical confining potential coming from the sub-Doppler part of a magneto-optical trapping force [30].…”

Section: B the Symmetric Regimesupporting

confidence: 64%

Two-temperature momentum distribution in a thulium magneto-optical trap

et al. 2017

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Second-stage laser cooling of thulium atoms at the 530.7 nm transition with a natural linewidth of 350 kHz offers an interesting possibility to study different regimes of a magneto-optical trap (MOT). The intermediate value of the spectral linewidth of the cooling transition allows the observation of three distinct regimes depending on the intensity and detuning of the cooling beams, namely, the "bowl-shaped" regime when light pressure force competes with gravity, the "double structure" regime with interplay between the Doppler and polarization-gradient (sub-Doppler) cooling, and the "symmetric" regime when Doppler cooling dominates over sub-Doppler cooling and gravity. The polarization-gradient cooling manifests itself by a two-temperature momentum distribution of atoms resulting in a double-structure of the spatial MOT profile consisting of a cold central fraction surrounded by a hot halo. We studied the double structure regime at different saturation parameters and compared observations with calculations based on semiclassical and quantum approaches. The quantum treatment adequately reproduces experimental results if the MOT magnetic field is properly taken into account.

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“…Along with contributing to 1 S 0 -1 P 1 MOT loss, 1 P 1 → 1 D 2 → 3 P 2 radiative decay continuously loads milli-Kelvin atoms in the 3 P 2 ͑m =1,2͒ states into a magnetic trap formed by the 1 S 0 -1 P 1 MOT quadrupole magnetic field [24][25][26][27][28][29][30]. Importantly, these samples are expected to display a wealth of binary collision resonances that arise due to an interplay between anisotropic quadrupole interactions and the local magnetic field [31][32][33].…”

Section: S 0 -1 P 1 Mot Precoolingmentioning

confidence: 99%

Narrow line cooling and momentum-space crystals

et al. 2004

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Narrow line laser cooling is advancing the frontier for experiments ranging from studies of fundamental atomic physics to high precision optical frequency standards. In this paper, we present an extensive description of the systems and techniques necessary to realize 689 nm 1 S 0 -3 P 1 narrow line cooling of atomic 88 Sr. Narrow line cooling and trapping dynamics are also studied in detail. By controlling the relative size of the power broadened transition linewidth and the single-photon recoil frequency shift, we show that it is possible to smoothly bridge the gap between semiclassical and quantum mechanical cooling. Novel semiclassical cooling processes, some of which explicitly depend on the relative size of gravity and the radiative force, are also explored. Moreover, for laser frequencies tuned above the atomic resonance, we demonstrate momentum-space crystals containing up to 26 well defined lattice points. Gravitationally assisted cooling is also achieved with blue-detuned light. Theoretically, we find the blue detuned dynamics are universal to Doppler limited systems. This paper offers the most comprehensive study of narrow line laser cooling to date.

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Magnetic trapping of metastable calcium atoms

Cited by 26 publications

References 15 publications

Sub-Doppler laser cooling and magnetic trapping of erbium

Sub-Doppler laser cooling and magnetic trapping of erbium

Two-temperature momentum distribution in a thulium magneto-optical trap

Narrow line cooling and momentum-space crystals

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