Your search keyword '"Ben Sherlock"' showing total 4 results

1. How weak is a weak probe in laser spectroscopy?

Author

Ben Sherlock and Ifan G. Hughes

Subjects

Physics, education.field_of_study, Opacity, Population, General Physics and Astronomy, chemistry.chemical_element, Laser, law.invention, Rubidium, Optical pumping, chemistry, law, Ultrafast laser spectroscopy, Atom, Physics::Atomic Physics, Atomic physics, Spectroscopy, education

Abstract

Laser spectroscopy experiments are often conducted with a probe that does not significantly alter the medium’s properties. For a two-level atom a clear measure of the strength of a probe beam in terms of the saturation intensity is known. We show that for a multilevel atom the situation is very different, and the effects of optical pumping are crucial to understanding the opacity of the medium. We present a simple theoretical analysis for Doppler-broadened spectroscopy of alkali metals on the D2 line that emphasizes the importance of the transient nature of the population dynamics, and the crucial role of the distribution of the times of flight of atoms through the probe beam. Experimental results are obtained with room temperature rubidium vapor probed by an extended-cavity diode laser and confirm our theoretical prediction.

Published

2009

2. Techniques to cool and rotate Bose-Einstein condensates in time-averaged adiabatic potentials

Author

Ben Sherlock, Christopher J. Foot, and M. Gildemeister

Subjects

Condensed Matter::Quantum Gases, Physics, Angular momentum, FOS: Physical sciences, chemistry.chemical_element, Atomic and Molecular Physics, and Optics, Vortex, law.invention, Magnetic field, Rubidium, chemistry, Quantum Gases (cond-mat.quant-gas), law, Ultracold atom, Physics::Atomic Physics, Atomic physics, Condensed Matter - Quantum Gases, Adiabatic process, Quantum, Bose–Einstein condensate

Abstract

We report two novel techniques for cooling and rotating Bose-Einstein condensates in a dilute rubidium vapour that highlight the control and versatility afforded over cold atom systems by time-averaged adiabatic potentials (TAAPs). The intrinsic loss channel of the TAAP has been successfully employed to evaporatively cool a sample of trapped atoms to quantum degeneracy. The speed and efficiency of this process compares well with that of conventional forced rf-evaporation. In an independent experiment, we imparted angular momentum to a cloud of atoms forming a Bose-Einstein condensate by introducing a rotating elliptical deformation to the TAAP geometry. Triangular lattices of up to 60 vortices were created. All findings reported herein result from straightforward adjustments of the magnetic fields that give rise to the TAAP., Comment: The first two authors contributed equally to this work

Published

2012

3. Publisher’s Note: Time-averaged adiabatic ring potential for ultracold atoms [Phys. Rev. A83, 043408 (2011)]

Author

E. Nugent, M. Gildemeister, Ben Sherlock, E. Owen, and Christopher J. Foot

Subjects

Physics, Quantization (physics), Ultracold atom, Adiabatic invariant, Quantum mechanics, Quantum dynamics, Supersymmetric quantum mechanics, Adiabatic process, Atomic and Molecular Physics, and Optics

Published

2011

4. Time-averaged adiabatic ring potential for ultracold atoms

Author

M. Gildemeister, E. Owen, Christopher J. Foot, E. Nugent, and Ben Sherlock

Subjects

Physics, Condensed Matter::Quantum Gases, Angular momentum, Condensed matter physics, Mathematics::Commutative Algebra, FOS: Physical sciences, Radius, Ring (chemistry), Atomic and Molecular Physics, and Optics, law.invention, Ultracold atom, law, Quantum Gases (cond-mat.quant-gas), Quadrupole, Physics::Atomic Physics, Atomic physics, Adiabatic process, Condensed Matter - Quantum Gases, Realization (systems), Bose–Einstein condensate

Abstract

We report the experimental realization of a versatile ring trap for ultracold atoms. The ring geometry is created by the time-averaged adiabatic potential resulting from the application of an oscillating magnetic bias field to a rf-dressed quadrupole trap. Lifetimes for a Bose-Einstein condensate in the ring exceed $11\mathrm{s}$ and the ring radius was continuously varied from $50 \ensuremath{\mu}\text{m}$ to $262 \ensuremath{\mu}\text{m}$. An efficient method of loading the ring from a conventional time-averaged orbiting potential trap is presented together with a rotation scheme which introduces angular momentum into the system. The ring presents an opportunity to study the superfluid properties of a condensate in a multiply connected geometry and also has applications for matter-wave interferometry.

Published

2011