Your search keyword '"Bouloufa, N."' showing total 3 results

1. Deeply bound cold caesium molecules formed after 0−gresonant coupling.

Author

Lignier, H., Fioretti, A., Horchani, R., Drag, C., Bouloufa, N., Allegrini, M., Dulieu, O., Pruvost, L., Pillet, P., and Comparat, D.

Abstract

Translationally cold caesium molecules are created by photoassociation below the 6s + 6p1/2excited state and selectively detected by resonance enhanced two photon ionization (RE2PI). A series of excited vibrational levels belonging to the 0−gsymmetry is identified. The regular progression of the vibrational spacings and of the rotational constants of the 0−g(6s + 6p1/2) levels is strongly altered in two energy domains. These deviations are interpreted in terms of resonant coupling with deeply bound energy levels of two upper 0−gstates dissociating into the 6s + 6p3/2and 6s + 5d3/2asymptotes. A theoretical model is proposed to explain the coupling and a quantum defect analysis of the perturbed level position is performed. Moreover, the resonant coupling changes dramatically the spontaneous decay products of the photoexcited molecules, strongly enhancing the decay into deeply bound levels of the a3Σ+utriplet state and of the X1Σ+gground state. These results may be relevant when conceiving population transferring schemes in cold molecule systems. [ABSTRACT FROM AUTHOR]

Published

2011

2. Deeply bound cold caesium molecules formed after 0(-)(g) resonant coupling.

Author

Lignier H, Fioretti A, Horchani R, Drag C, Bouloufa N, Allegrini M, Dulieu O, Pruvost L, Pillet P, and Comparat D

Abstract

Translationally cold caesium molecules are created by photoassociation below the 6s + 6p(1/2) excited state and selectively detected by resonance enhanced two photon ionization (RE2PI). A series of excited vibrational levels belonging to the 0(-)(g) symmetry is identified. The regular progression of the vibrational spacings and of the rotational constants of the 0(-)(g) (6s + 6p(1/2)) levels is strongly altered in two energy domains. These deviations are interpreted in terms of resonant coupling with deeply bound energy levels of two upper 0(-)(g) states dissociating into the 6s + 6p(3/2) and 6s + 5d(3/2) asymptotes. A theoretical model is proposed to explain the coupling and a quantum defect analysis of the perturbed level position is performed. Moreover, the resonant coupling changes dramatically the spontaneous decay products of the photoexcited molecules, strongly enhancing the decay into deeply bound levels of the a(3)Σ(+)(u) triplet state and of the X(1)Σ(+)(g) ground state. These results may be relevant when conceiving population transferring schemes in cold molecule systems.

Published

2011

3. Molecular spectroscopy for ground-state transfer of ultracold RbCs molecules.

Author

Debatin M, Takekoshi T, Rameshan R, Reichsöllner L, Ferlaino F, Grimm R, Vexiau R, Bouloufa N, Dulieu O, and Nägerl HC

Abstract

We perform one- and two-photon high resolution spectroscopy on ultracold samples of RbCs Feshbach molecules with the aim to identify a suitable route for efficient ground-state transfer in the quantum-gas regime to produce quantum gases of dipolar RbCs ground-state molecules. One-photon loss spectroscopy allows us to probe deeply bound rovibrational levels of the mixed excited (A(1)Σ(+)-b(3)Π)0(+) molecular states. Two-photon dark state spectroscopy connects the initial Feshbach state to the rovibronic ground state. We determine the binding energy of the lowest rovibrational level |v'' = 0, J'' = 0> of the X(1)Σ(+) ground state to be D = 3811.5755(16) cm(-1), a 300-fold improvement in accuracy with respect to previous data. We are now in the position to perform stimulated two-photon Raman transfer to the rovibronic ground state.

Published

2011