4 research outputs found
Wave behaviour and noncomplementary particle behaviour in the same experiment
Grangier, Roger and Aspect have recently performed beautiful experiments, which show that the same single photon source shows wave behaviour or particle behaviour depending on the experimental arrangement. We propose experiments in which quantum mechanics predicts wave behaviour and noncomplementary particle behaviour in the same experiment
Atom laser divergence
5 pages, 3 figures. V3: as will appear in Phys. Rev. Lett.; RevTeX 4.0We measure the angular divergence of a quasi-continuous, rf-outcoupled, free-falling atom laser as a function of the outcoupling frequency. The data is compared to a Gaussian-beam model of laser propagation that generalizes the standard formalism of photonic lasers. Our treatment includes diffraction, magnetic lensing, and interaction between the atom laser and the condensate. We find that the dominant source of divergence is the condensate-laser interaction
Partially ferromagnetic electromagnet for trapping and cooling neutral atoms to quantum degeneracy
International audienceWe have developed a compact partially ferromagnetic electromagnet to produce a Ioffe-Pritchard trap for neutral atoms. Our structure permits strong magnetic confinement with low power consumption. Compared to the previous iron-core electromagnet, it allows for easy compensation of remnant fields and very high stability, along with cost-effective realization and compactness. We describe and characterize our apparatus and demonstrate trapping and cooling of Rb 87 atoms to quantum degeneracy. Pure Bose-Einstein condensates containing 10^6 atoms are routinely realized on a half-minute cycle. In addition we test the stability of the magnetic trap by producing atom lasers
Toward a pulsed antihydrogen beam for WEP tests in AEgIS
The AEg̅IS collaboration at CERN’s AD produces antihydrogen atoms in the form of a pulsed, isotropic source with a precisely defined formation time. AEg̅IS has recently undergone major upgrades to fully benefit from the increased number of colder antiprotons provided by the new ELENA decelerator and to move toward forming a horizontal beam to directly investigate the influence of gravity on the H̅ atoms, thereby probing the Weak Equivalence Principle for antimatter. This contribution gives an overview of these upgrades as well as subsequent results from the first beam times with ELENA