Continuous loading of a magnetic trap

Stühler, J.; Schmidt, Piet O.; Hensler, S.; Werner, J.H.; Mlynek, J.; Pfau, Tilman

doi:10.1103/physreva.64.031405

Cited by 70 publications

(90 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The only other parameter which is not negligible is the inelastic two-body loss parameter, which is measured independently in our experiment (see below). The main conclusion of our analysis at high RF frequencies is that inelastic collisions with atoms from the MOT limit the total number of atoms that are accumulated in the MT, and produce a strong heating: the temperature of the atoms in the MT, which, in absence of collisions, could be as low at T MOT /3 [2], raises to about 100 µK for large RF frequencies. This drastically limits the achieved steady state phase-space density.…”

Section: Theoretical Model and Interpretationmentioning

confidence: 95%

“…As in [2] and [6], chromium atoms in the 7 S 3 ground state are captured in a MOT, and depumped to dark metastable states 5 D 4,3 . We observe different regimes as a function of the RF frequency.…”

mentioning

confidence: 99%

“…Spontaneous emission from the excited state of the cooling transition depumps atoms into a dark metastable state, which can be trapped, either optically, or magnetically. This provides an interesting means to continuously accumulate atoms in a magnetic trap [2], or for a continuous loading of an optical or magnetic waveguide. Cold metastable atoms are directly produced inside the waveguide or the trap, which reduces heating associated with the sequential loading from a MOT.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Accumulation and thermalization of cold atoms in a finite-depth magnetic trap

et al. 2007

View full text Add to dashboard Cite

We experimentally and theoretically study the continuous accumulation of cold atoms from a magneto-optical trap (MOT) into a finite depth trap, consisting in a magnetic quadrupole trap dressed by a radiofrequency (RF) field. Chromium atoms ( 52 Cr) in a MOT are continuously optically pumped by the MOT lasers to metastable dark states. In presence of a RF field, the temperature of the metastable atoms that remain magnetically trapped can be as low as 25 µK, with a density of 10 17 atoms.m −3 , resulting in an increase of the phase-space density, still limited to 7.10 −6 by inelastic collisions. To investigate the thermalization issues in the truncated trap, we measure the free evaporation rate in the RF-truncated magnetic trap, and deduce the average elastic cross section for atoms in the 5 D4 metastable states, σ el = 7.0 × 10 −16 m 2 . We finally discuss the possibilities for using this scheme of continuous accumulation and RF evaporation to rapidly reach high phase-space densities from a MOT.PACS numbers: 32.80. Pj, 47.45.Ab, 32.80.Cy Magneto-optical trapping is one of the greatest recent advances in atomic and molecular physics, opening many new areas in physics, including the study of Bose-Einstein condensation in dilute systems. One of the advantages of a magneto-optical trap (MOT), is that cooling and trapping are simultaneous. However, inherent limitations of the cooling mechanism, for example light-assisted collisions or multiple scattering of light, limit typical phasespace densities to 10 −7 when strong fluorescence lines are involved in the cooling transition [1]. To reach higher phase-space densities, it is usually necessary to use sequential operations, such as cooling in molasses, loading in conservative traps, and forced evaporation, which greatly limits the rate at which a Bose-Einstein condensates (BEC) can be produced.New possibilities arise for atoms whose electronic level structure includes metastable dark states (such as Sr, Er, Yb, or Cr). Spontaneous emission from the excited state of the cooling transition depumps atoms into a dark metastable state, which can be trapped, either optically, or magnetically. This provides an interesting means to continuously accumulate atoms in a magnetic trap [2], or for a continuous loading of an optical or magnetic waveguide. Cold metastable atoms are directly produced inside the waveguide or the trap, which reduces heating associated with the sequential loading from a MOT. This may have promising applications in the prospect of continuously producing a coherent beam of atoms, by performing forced evaporation as the atoms propagate along a waveguide [3].In this paper, we study the accumulation of metastable chromium atoms in a magnetic trap (MT), dressed by a radiofrequency (RF) field (see Fig 1) . We observe different regimes as a function of the RF frequency. When the RF frequency is small, atoms in internal states adiabatically connected to high field seeking states at small magnetic fields are accumulated in a (3D) W-shaped potential. When the RF ...

show abstract

Section: Theoretical Model and Interpretationmentioning

confidence: 95%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Accumulation and thermalization of cold atoms in a finite-depth magnetic trap

et al. 2007

View full text Add to dashboard Cite

show abstract

“…Processes occurring in the cold regime are sensitive to the details of the interaction potentials between the colliding systems over an extended range of internuclear separations. Recent experiments with chromium [4,5,6,7] emphasize the need for theoretical studies of Cr scattering properties. The interest in cooling Cr stems from its particular properties; in its ground state 7 S 3 , it possesses a very large magnetic moment, 6 µ B (µ B : Bohr magneton), making it an ideal atom for buffer-cooling in a purely magnetic trap [7], as well as for magneto-optical trapping [4].…”

mentioning

confidence: 99%

Collisional properties of trapped cold chromium atoms

Pavlović

Roos²,

Côté

et al. 2004

Phys. Rev. A

View full text Add to dashboard Cite

We report on calculations of the elastic cross section and thermalization rate for collision between two maximally spin-polarized chromium atoms in the cold and ultracold regimes, relevant to buffergas and magneto-optical cooling of chromium atoms. We calculate ab initio potential energy curves for Cr2 and the van der Waals coefficient C6, and construct interaction potentials between two colliding Cr atoms. We explore the effect of shape resonances on elastic cross section, and find that they dramatically affect the thermalization rate. Our calculated value for the s-wave scattering length is compared in magnitude with a recent measurement at ultracold temperatures.Collisions of atoms at ultracold temperatures have received considerable attention because of their importance in cooling and trapping of atoms [1] and their role in high precision spectroscopy [2] and Bose-Einstein condensation [3]. Processes occurring in the cold regime are sensitive to the details of the interaction potentials between the colliding systems over an extended range of internuclear separations. Recent experiments with chromium [4,5,6,7] emphasize the need for theoretical studies of Cr scattering properties. The interest in cooling Cr stems from its particular properties; in its ground state 7 S 3 , it possesses a very large magnetic moment, 6 µ B (µ B : Bohr magneton), making it an ideal atom for buffer-cooling in a purely magnetic trap [7], as well as for magneto-optical trapping [4]. In addition, anisotropic long-range interactions, such as chromium's magnetic dipole-dipole interactions, may lead to novel phenomena in BECs [9,10]. The existence of a stable fermionic isotope, 53 Cr, opens the possibility of obtaining fermionic degenerate gas using sympathetic cooling. Chromium was also used in a new cooling scheme [5], where ultracold chromium atoms were loaded from a MOT into an Ioffe-Pritchard magnetic trap, and cooled below 100µK. However, a not so-desirable byproduct of large-spin collision is inelastic "bad" scattering rates that deplete the trap.On the theoretical front, the electronic spectrum of the Cr 2 dimer poses a considerable numerical challenge. Chromium is the first atom in the periodic table with a half-filled d shell (the ground electronic configuration is Cr(3d 5 4s, 7 S)) and the Cr 2 dimer is one of the most extreme cases of multiple metal-metal bonding. To date, the best attempt to calculate its interaction potential curves is a multiconfiguration second-order perturbation theory with complete active space self-consistent field (CASSCF/CASPT2) [11,12]. While some information on the spectroscopy of the ground electronic state ( 1 Σ + g molecular symmetry) exists, there is no data available for the interaction of two maximally spin-stretched Cr atoms in the 13 Σ + g molecular symmetry, i.e. total spin, S = 6. In this communication, we explore the collisional properties of Cr atoms in the cold and ultracold temperature regimes by revisiting the electronic structure of the dimer. More accurate Born-Oppenheimer potenti...

show abstract

“…This relationship demonstrates the connection between the deceleration force and the final effective temperature in this scheme. After their longitudinal momentum space density has been compressed, molecules can be subjected to a similar single-photon cooling step in position space through position-sensitive optical pumping into a trap [23,45,50,52]. In principle, each molecule needs to spontaneously emit only two photons during the entire process from beam to trap, demonstrating the large capacity each spontaneously emitted photon has for carrying away entropy.…”

Section: Phase-space Compressionmentioning

confidence: 99%

Continuous all-optical deceleration and single-photon cooling of molecular beams

et al. 2014

View full text Add to dashboard Cite

Ultracold molecular gases are promising as an avenue to rich many-body physics, quantum chemistry, quantum information, and precision measurements. This richness, which flows from the complex internal structure of molecules, makes the creation of ultracold molecular gases using traditional methods (laser plus evaporative cooling) a challenge, in particular due to the spontaneous decay of molecules into dark states. We propose a way to circumvent this key bottleneck using an alloptical method for decelerating molecules using stimulated absorption and emission with a single ultrafast laser. We further describe single-photon cooling of the decelerating molecules that exploits their high dark state pumping rates, turning the principal obstacle to molecular laser cooling into an advantage. Cooling and deceleration may be applied simultaneously and continuously to load molecules into a trap. We discuss implementation details including multi-level numerical simulations of strontium monohydride (SrH). These techniques are applicable to a large number of molecular species and atoms with the only requirement being an electric dipole transition that can be accessed with an ultrafast laser.

show abstract

Continuous loading of a magnetic trap

Cited by 70 publications

References 25 publications

Accumulation and thermalization of cold atoms in a finite-depth magnetic trap

Accumulation and thermalization of cold atoms in a finite-depth magnetic trap

Collisional properties of trapped cold chromium atoms

Continuous all-optical deceleration and single-photon cooling of molecular beams

Contact Info

Product

Resources

About