4 research outputs found
Coherent control of population transfer between vibrational states in an optical lattice via two-path quantum interference
We demonstrate coherent control of population transfer between vibrational
states in an optical lattice by using interference between a one-phonon
transition at and a two-phonon transition at . The
and transitions are driven by phase- and amplitude-modulation of the
lattice laser beams, respectively. By varying the relative phase between these
two pathways, we control the branching ratio of transitions to the first
excited state and to the higher states. Our best result shows an improvement of
the branching ratio by a factor of 3.50.7. Such quantum control techniques
may find broad application in suppressing leakage errors in a variety of
quantum information architectures.Comment: 5 pages, 4 figure
Coherence freeze in an optical lattice investigated via pump-probe spectroscopy
Motivated by our observation of fast echo decay and a surprising coherence
freeze, we have developed a pump-probe spectroscopy technique for vibrational
states of ultracold Rb atoms in an optical lattice to gain information
about the memory dynamics of the system. We use pump-probe spectroscopy to
monitor the time-dependent changes of frequencies experienced by atoms and to
characterize the probability distribution of these frequency trajectories. We
show that the inferred distribution, unlike a naive microscopic model of the
lattice, correctly predicts the main features of the observed echo decay.Comment: 4 pages, 5 figure
Investigation of Coherence and its Decay Mechanisms in an Optical Lattice
In this thesis, I report on experiments with cold 85Rb atoms in a far-detuned one-dimensional optical lattice. These experiments are focused on creating efficient coupling between the quantized vibrational states of atoms in the optical lattice, on controlling and maintaining coherence between the vibrational states, and on developing a spectroscopy method to characterize the decay of coherence. First, I present an experimental study of the application of simple and compound pulses consisting of time-dependent spatial translations to coupling vibrational states of ultracold 85Rb atoms in the optical
lattice. Experimental results show that a square pulse consisting of lattice displacements and a delay is more efficient than single-step and Gaussian pulses. The square pulse can be seen as an example of coherent control. Numerical calculations are in strong agreement with the experimental results. In addition, it is shown numerically that the vibrational state coupling due to such lattice manipulations is more efficient in shallow lattices than in deep lattices, in which the coupling probability approaches the harmonic
oscillator limit. Next, the effectiveness of these pulses in reviving oscillations of atoms in vibrational superposition states using a pulse-echo technique is examined. Experimental results show that the square and Gaussian pulses result in higher echo amplitudes than the single-step pulse. These echo amplitudes are an order of magnitude larger than the echo amplitudes observed previously for the motional states of atoms in optical lattices.
With the aim of the optimized square echo pulse, echo amplitude is measured at much
longer times, where a surprising coherence freeze (plateau) is observed. To investigate
mechanisms responsible for the observed echo decay and the coherence freeze, we developed
a new two-dimensional pump-probe spectroscopy technique to monitor the evolution of frequency-frequency correlations in the system, a necessary input for understanding the decay of coherence. Through this 2D technique, we have characterized the temporal decay of frequency memory and through our simulations we find that coherence freeze is related to the shape of this memory loss function. This technique is general in that it can be applied in a variety of quantum information candidate systems to probe the nature of their decoherence.Ph