C. MacCormick scite author profile

There is a pressing need for robust and straightforward methods to create potentials for trapping Bose-Einstein condensates which are simultaneously dynamic, fully arbitrary, and sufficiently stable to not heat the ultracold gas. We show here how to accomplish these goals, using a rapidly-moving laser beam that "paints" a timeaveraged optical dipole potential in which we create BECs in a variety of geometries, including toroids, ring lattices, and square lattices. Matter wave interference patterns confirm that the trapped gas is a condensate. As a simple illustration of dynamics, we show that the technique can transform a toroidal condensate into a ring lattice and back into a toroid. The technique is general and should work with any sufficiently polarizable low-energy particles.

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Coherent control of mesoscopic atomic ensembles for quantum information

Бетеров¹,

Saffman²,

Zhukov³

et al. 2014

Laser Phys.

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Quantum gates in mesoscopic atomic ensembles based on adiabatic passage and Rydberg blockade

et al. 2013

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We present schemes for geometric phase compensation in an adiabatic passage which can be used for the implementation of quantum logic gates with atomic ensembles consisting of an arbitrary number of strongly interacting atoms. Protocols using double sequences of stimulated Raman adiabatic passage (STIRAP) or adiabatic rapid passage (ARP) pulses are analyzed. Switching the sign of the detuning between two STIRAP sequences, or inverting the phase between two ARP pulses, provides state transfer with well-defined amplitude and phase independent of atom number in the Rydberg blockade regime. Using these pulse sequences we present protocols for universal single-qubit and two-qubit operations in atomic ensembles containing an unknown number of atoms.

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Deterministic single-atom excitation via adiabatic passage and Rydberg blockade

et al. 2011

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We propose to use adiabatic rapid passage with a chirped laser pulse in the strong dipole blockade regime to deterministically excite only one Rydberg atom from randomly loaded optical dipole traps or optical lattices. The chirped laser excitation is shown to be insensitive to the random number N of the atoms in the traps. Our method overcomes the problem of the √ N dependence of the collective Rabi frequency, which was the main obstacle for deterministic single-atom excitation in the ensembles with unknown N, and can be applied for single-atom loading of dipole traps and optical lattices.

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Quantum simulation of electron–phonon interactions in strongly deformable materials

Hague

MacCormick

2012

New J. Phys.

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View the article online for updates and enhancements. Abstract. We propose an approach for quantum simulation of electron-phonon interactions using Rydberg states of cold atoms and ions. We show how systems of cold atoms and ions can be mapped onto electron-phonon systems of the Su-Schrieffer-Heeger type. We discuss how properties of the simulated Hamiltonian can be tuned and how to read physically relevant properties from the simulator. In particular, use of painted spot potentials offers a high level of tunability, enabling all physically relevant regimes of the electron-phonon Hamiltonian to be accessed. Contents

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C. MacCormick

Experimental demonstration of painting arbitrary and dynamic potentials for Bose–Einstein condensates

Coherent control of mesoscopic atomic ensembles for quantum information

Quantum gates in mesoscopic atomic ensembles based on adiabatic passage and Rydberg blockade

Deterministic single-atom excitation via adiabatic passage and Rydberg blockade

Quantum simulation of electron–phonon interactions in strongly deformable materials

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