Ultrafast laser-driven Rabi oscillations of a trapped atomic vapor

Abstract: We investigate Rabi oscillation of an atom ensemble in Gaussian spatial distribution. By using the ultrafast laser interaction with the cold atomic rubidium vapor spatially confined in a magnetooptical trap, the oscillatory behavior of the atom excitation is probed as a function of the laser pulse power. Theoretical model calculation predicts that the oscillation peaks of the ensemble-atom Rabi flopping fall on the simple Rabi oscillation curve of a single atom and the experimental result shows good agreement … Show more

“…(16) and (17) are confirmed. The theoretical calculations are respectively plotted with dashed lines, of which the deviation from the experimental result is due to the spatially inhomogeneous laser interaction with the atom ensemble [30]. When the spatial averaging effect is taken into account (by assuming the Gaussian laser beam and atom ensemble size ratio is 2.5), the new calculations, shown with solid lines, agree well with the experimental results.…”

“…The signal linearity was assured by operating the experiment in the one-photon perturbation regime. The error due to three-photon ionizations by the pump pulse was estimated below 5% at a pulse-area of 3π [30], which was negligible in the considered experimental con-dition. The whole experiment (four steps: MOT-turn off, laser-control, ionization, MOT-turn on) was repeated at 2 Hz by cyclically turning on and off three mechanical shutters.…”

Rabi oscillations of Morris-Shore–transformedN-state systems by elliptically polarized ultrafast laser pulses

“…(16) and (17) are confirmed. The theoretical calculations are respectively plotted with dashed lines, of which the deviation from the experimental result is due to the spatially inhomogeneous laser interaction with the atom ensemble [30]. When the spatial averaging effect is taken into account (by assuming the Gaussian laser beam and atom ensemble size ratio is 2.5), the new calculations, shown with solid lines, agree well with the experimental results.…”

“…The signal linearity was assured by operating the experiment in the one-photon perturbation regime. The error due to three-photon ionizations by the pump pulse was estimated below 5% at a pulse-area of 3π [30], which was negligible in the considered experimental con-dition. The whole experiment (four steps: MOT-turn off, laser-control, ionization, MOT-turn on) was repeated at 2 Hz by cyclically turning on and off three mechanical shutters.…”

Rabi oscillations of Morris-Shore–transformedN-state systems by elliptically polarized ultrafast laser pulses

“…Experimental investigation of the subpicosecond X rotation of the atomic clock states was performed in a setup described in our early works [25][26][27]. The setup composed of a magneto-optical trap (MOT) [28] for cold rubidium atoms ( 87 Rb) and a femtosecond laser amplifier [29].…”

Subpicosecond X rotations of atomic clock states

“…By adjusting the diameters of the cooling and repumping laser beams, an atomic cloud of about 200 µm diameter and 6 × 10 9 cm 3 atom density was prepared. The atoms were tightly confined in particular to achieve a uniform laseratom interaction [27]. When the laser pulses were focused on to the atomic vapor, the laser beam diameter of 600 µm was about 3 times bigger than the diameter of the atom cloud.…”

Quantum dynamics of a two-state system induced by a chirped zero-area pulse