We experimentally demonstrate fast separation of a two-ion crystal in a
microstructured segmented Paul trap. By the use of spectroscopic calibration
routines for the electrostatic trap potentials, we achieve the required precise
control of the ion trajectories near the \textit{critical point}, where the
harmonic confinement by the external potential vanishes. The separation
procedure can be controlled by three parameters: A static potential tilt, a
voltage offset at the critical point, and the total duration of the process. We
show how to optimize the control parameters by measurements of ion distances,
trap frequencies and the final motional excitation. At a separation duration of
$80 \mu$s, we achieve a minimum mean excitation of $\bar{n} = 4.16(0.16)$
vibrational quanta per ion, which is consistent with the adiabatic limit given
by our particular trap. We show that for fast separation times, oscillatory
motion is excited, while a predominantly thermal state is obtained for long
times. The presented technique does not rely on specific trap geometry
parameters and can therefore be adopted for different segmented traps
We evaluate the feasibility of the implementation of two quantum repeater protocols with an existing experimental platform based on a 40 Ca + -ion in a segmented micro trap, and a third one that requires small changes to the platform. A fiber cavity serves as an ion-light interface. Its small mode volume allows for a large coupling strength of g c = 2π × 20 MHz despite comparatively large losses κ = 2π × 18.3 MHz. With a fiber diameter of 125 μm, the cavity is integrated into the microstructured ion trap, which in turn is used to transport single ions in and out of the interaction zone in the fiber cavity. We evaluate the entanglement generation rate for a given fidelity using parameters from the experimental setup. The DLCZ protocol [1] and the hybrid protocol [2] outperform the EPR protocol [3]. We calculate rates of more than than 100 s −1 for non-local Bell state fidelities larger than 0.95 with the existing platform. We identify parameters which mainly limit the attainable rates, and conclude that entanglement generation rates of 750 s −1 at fidelities of 0.95 are within reach with current technology. arXiv:1508.05272v2 [quant-ph]
In recent literature on trapped ultracold atomic gases, calculations for 2D-systems are often done within the Dynamical Mean Field Theory (DMFT) approximation. In this paper, we compare DMFT to a fully two-dimensional, self-consistent second order perturbation theory for weak interactions in a repulsive Fermi-Hubbard model. We investigate the role of quantum and of spatial fluctuations when the system is in the antiferromagnetic phase, and find that, while quantum fluctuations decrease the order parameter and critical temperatures drastically, spatial fluctuations only play a noticeable role when the system undergoes a phase transition, or at phase boundaries in the trap. We conclude from this that DMFT is a good approximation for the antiferromagnetic Fermi-Hubbard model for experimentally relevant system sizes.
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