David Lucas

Keeping a single qubit alive by experimental dynamic decoupling

Journal of Physics B: Atomic, Molecular and Optical Physics 44:2 (2011)

Authors:

DJ Szwer, SC Webster, AM Steane, DM Lucas

Abstract:

We demonstrate the use of dynamic decoupling techniques to extend the coherence time of a single memory qubit by nearly two orders of magnitude. By extending the Hahn spin-echo technique to correct for unknown, arbitrary polynomial variations in the qubit precession frequency, we show analytically that the required sequence of π-pulses is identical to the Uhrig dynamic decoupling (UDD) sequence. We compare UDD and Carr-Purcell-Meiboom-Gill (CPMG) sequences applied to a single 43Ca+ trapped-ion qubit and find that they afford comparable protection in our ambient noise environment. © 2011 IOP Publishing Ltd.

Reduction of heating rate in a microfabricated ion trap by pulsed-laser cleaning

NEW JOURNAL OF PHYSICS 13 (2011) ARTN 123023

Authors:

DTC Allcock, L Guidoni, TP Harty, CJ Ballance, MG Blain, AM Steane, DM Lucas

Keeping a Single Qubit Alive by Experimental Dynamic Decoupling

(2010)

Authors:

David J Szwer, Simon C Webster, Andrew M Steane, David M Lucas

Scalable simultaneous multiqubit readout with 99.99% single-shot fidelity

Physical Review A - Atomic, Molecular, and Optical Physics 81:4 (2010)

Authors:

AH Burrell, DJ Szwer, SC Webster, DM Lucas

Abstract:

We describe single-shot readout of a trapped-ion multiqubit register using space- and time-resolved camera detection. For a single qubit we measure 0.9(3)×10-4 readout error in 400μs exposure time, limited by the qubit's decay lifetime. For a four-qubit register (a "qunybble"), we measure an additional error of only 0.1(1)×10-4 per qubit, despite the presence of 4% optical cross-talk between neighboring qubits. A study of the cross-talk indicates that the method would scale with a negligible loss of fidelity to 10000 qubits at a density of 1 qubit/μm2, with a readout time of 1μs/qubit. © 2010 The American Physical Society.

Implementation of a symmetric surface electrode ion trap with field compensation using a modulated Raman effect

ArXiv 0909.3272 (2009)

Authors:

DTC Allcock, JA Sherman, DN Stacey, AH Burrell, MJ Curtis, G Imreh, NM Linke, DJ Szwer, SC Webster, AM Steane, DM Lucas

Abstract:

We describe the fabrication and characterization of a new surface-electrode Paul ion trap designed for experiments in scalable quantum information processing with Ca+. A notable feature is a symmetric electrode pattern which allows rotation of the normal modes of ion motion, yielding efficient Doppler cooling with a single beam parallel to the planar surface. We propose and implement a technique for micromotion compensation in all directions using an infrared repumper laser beam directed into the trap plane. Finally, we employ an alternate repumping scheme that increases ion fluorescence and simplifies heating rate measurements obtained by time-resolved ion fluorescence during Doppler cooling.