Tim Freegarde scite author profile

We present a one-dimensional scattering theory which enables us to describe a wealth of effects arising from the coupling of the motional degree of freedom of scatterers to the electromagnetic field. Multiple scattering to all orders is taken into account. The theory is applied to describe the scheme of a Fabry-Perot resonator with one of its mirrors moving. The friction force, as well as the diffusion, acting on the moving mirror is derived. In the limit of a small reflection coefficient, the same model provides for the description of the mechanical effect of light on an atom moving in front of a mirror.

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Nontrivial Phase Coupling in Polariton Multiplets

Ohadi

Gregory

Freegarde

et al. 2016

Phys. Rev. X

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Composite pulses for interferometry in a thermal cold atom cloud

et al. 2014

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Atom interferometric sensors and quantum information processors must maintain coherence while the evolving quantum wavefunction is split, transformed and recombined, but suffer from experimental inhomogeneities and uncertainties in the speeds and paths of these operations. Several error-correction techniques have been proposed to isolate the variable of interest. Here we apply composite pulse methods to velocity-sensitive Raman state manipulation in a freely-expanding thermal atom cloud. We compare several established pulse sequences, and follow the state evolution within them. The agreement between measurements and simple predictions shows the underlying coherence of the atom ensemble, and the inversion infidelity in an 80 micro-Kelvin atom cloud is halved. Composite pulse techniques, especially if tailored for atom interferometric applications, should allow greater interferometer areas, larger atomic samples and longer interaction times, and hence improve the sensitivity of quantum technologies from inertial sensing and clocks to quantum information processors and tests of fundamental physics

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Optimal control of mirror pulses for cold-atom interferometry

et al. 2018

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Atom matterwave interferometry requires mirror and beam splitter pulses that are robust to inhomogeneities in field intensity, magnetic environment, atom velocity, and Zeeman substate. We present theoretical results which show that pulse shapes determined using quantum control methods can significantly improve interferometer performance by allowing broader atom distributions, larger interferometer areas, and higher contrast. We have applied gradient ascent pulse engineering (GRAPE) to optimize the design of phase-modulated mirror pulses for a Mach-Zehnder light-pulse atom interferometer, with the aim of increasing fringe contrast when averaged over atoms with an experimentally relevant range of velocities, beam intensities, and Zeeman states. Pulses were found to be highly robust to variations in detuning and coupling strength and offer a clear improvement in robustness over the best established composite pulses. The peak mirror fidelity in a cloud of ∼ 80 μK 85 Rb atoms is predicted to be improved by a factor of 2 compared with standard rectangular π pulses.

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Confinement and manipulation of atoms using short laser pulses

Freegarde

Walz

Hänsch

1995

Optics Communications

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Tim Freegarde

Scattering theory of cooling and heating in optomechanical systems

Nontrivial Phase Coupling in Polariton Multiplets

Composite pulses for interferometry in a thermal cold atom cloud

Optimal control of mirror pulses for cold-atom interferometry

Confinement and manipulation of atoms using short laser pulses

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