Ultracold quantum matter

Inelastic collisions in radiofrequency-dressed mixtures of ultracold atoms

(2019)

Authors:

Elliot Bentine, Adam J Barker, Kathrin Luksch, Shinichi Sunami, Tiffany L Harte, Ben Yuen, Christopher J Foot, Daniel J Owens, Jeremy M Hutson

Raman quantum memory with built-in suppression of four-wave-mixing noise

Physical Review A American Physical Society 100:3 (2019) 033801

Authors:

Thomas, Thomas Hird, J Munns, B Brecht, D Saunders, J Nunn, IA Walmsley, PM Ledingham

Abstract:

Quantum memories are essential for large-scale quantum information networks. Along with high efficiency, storage lifetime, and optical bandwidth, it is critical that the memory adds negligible noise to the recalled signal. A common source of noise in optical quantum memories is spontaneous four-wave mixing. We develop and implement a technically simple scheme to suppress this noise mechanism by means of quantum interference. Using this scheme with a Raman memory in warm atomic vapor, we demonstrate over an order of magnitude improvement in noise performance. Furthermore we demonstrate a method to quantify the remaining noise contributions and present a route to enable further noise suppression. Our scheme opens the way to quantum demonstrations using a broadband memory, significantly advancing the search for scalable quantum photonic networks.

Applying machine learning optimization methods to the production of a quantum gas

(2019)

Authors:

Adam J Barker, Harry Style, Kathrin Luksch, Shinichi Sunami, David Garrick, Felix Hill, Christopher J Foot, Elliot Bentine

(py)LIon: a package for simulating trapped ion trajectories

(2019)

Authors:

E Bentine, CJ Foot, D Trypogeorgos

Probing multiple-frequency atom-photon interactions with ultracold atoms

New Journal of Physics IOP Publishing 21:5 (2019) 073067

Authors:

Kathrin Luksch, Elliot Bentine, Adam Barker, Shinichi Sunami, TL Harte, Ben Yuen, Christopher Foot

Abstract:

We dress atoms with multiple-radiofrequency fields and investigate the spectrum of transitions driven by an additional probe field. A complete theoretical description of this rich spectrum is presented, in which we find allowed transitions and determine their amplitudes using the resolvent formalism. Experimentally, we observe transitions up to sixth order in the probe field using radiofrequency spectroscopy of Bose-Einstein condensates trapped in single- and multiple-radiofrequency-dressed potentials. We find excellent agreement between theory and experiment, including the prediction and verification of previously unobserved transitions, even in the single-radiofrequency case.