Collisional Narrowing and Dynamical Decoupling in a Dense Ensemble of Cold Atoms

This book presents an experimental and theoretical study of the coherent properties of trapped atomic ensembles at high densities. It points towards a means of making atom ensembles more useful in future quantum computers.

Ultra-cold atomic ensembles have emerged in recent years as a powerful tool in many-body physics research, quantum information science and metrology. This thesis presents an experimental and theoretical study of the coherent properties of trapped atomic ensembles at high densities, which are essential to many of the aforementioned applications. The study focuses on how inter-particle interactions modify the ensemble coherence dynamics, and whether it is possible to extend the coherence time by means of external control. The thesis presents a theoretical model which explains the effect of elastic collision of the coherence dynamics and then reports on experiments which test this model successfully in the lab. Furthermore, the work includes the first implementation of dynamical decoupling with ultra-cold atomic ensembles. It is demonstrated experimentally that by using dynamical decoupling the coherence time can be extended 20-fold. This has a great potential to increase the usefulness of these ensembles for quantum computation.

Points towards means of making atom ensembles more useful in future quantum computers Backs up a novel theoretical model of coherence dynamics with experimental tests Nominated as an outstanding contribution by the Weizmann Institute of Science Includes supplementary material: sn.pub/extras

Inhalt
The Experimental Setup.- Theoretical Framework.- Spectral Narrowing due to Elastic Collisions.- The Ensemble Spectrum with an Arbitrary Detuning Distribution.- Motional Broadening in Ensembles with Heavy-tail Detuning Distribution.- Suppression of Collisional Decoherence by Dynamical Decoupling.