Dr Christopher Ballance

Heating rate and electrode charging measurements in a scalable, microfabricated, surface-electrode ion trap

Applied Physics B: Lasers and Optics 107:4 (2012) 913-919

Authors:

DTC Allcock, TP Harty, HA Janacek, NM Linke, CJ Ballance, AM Steane, DM Lucas, RL Jarecki, SD Habermehl, MG Blain, D Stick, DL Moehring

Abstract:

We characterise the performance of a surfaceelectrode ion "chip" trap fabricated using established semiconductor integrated circuit and micro-electro-mechanicalsystem (MEMS) microfabrication processes, which are in principle scalable to much larger ion trap arrays, as proposed for implementing ion trap quantum information processing. We measure rf ion micromotion parallel and perpendicular to the plane of the trap electrodes, and find that on-package capacitors reduce this to <~10 nm in amplitude.We also measure ion trapping lifetime, charging effects due to laser light incident on the trap electrodes, and the heating rate for a single trapped ion. The performance of this trap is found to be comparable with others of the same size scale. © Springer-Verlag 2011.

Background-free detection of trapped ions

(2011)

Authors:

NM Linke, DTC Allcock, DJ Szwer, CJ Ballance, TP Harty, HA Janacek, DN Stacey, AM Steane, DM Lucas

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

(2011)

Authors:

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

Heating rate and electrode charging measurements in a scalable, microfabricated, surface-electrode ion trap

(2011)

Authors:

DTC Allcock, TP Harty, HA Janacek, NM Linke, CJ Ballance, AM Steane, DM Lucas, RL Jarecki, SD Habermehl, MG Blain, D Stick, DL Moehring

Background-free detection of trapped ions

Applied Physics B: Lasers and Optics (2011) 1-6

Authors:

NM Linke, DTC Allcock, DJ Szwer, CJ Ballance, TP Harty, HA Janacek, DN Stacey, AM Steane, DM Lucas

Abstract:

We demonstrate a Doppler cooling and detection scheme for ions with low-lying D levels which almost entirely suppresses scattered laser light background, while retaining a high fluorescence signal and efficient cooling. We cool a single ion with a laser on the {Mathematical expression} transition as usual, but repump via the {Mathematical expression} level. By filtering out light on the cooling transition and detecting only the fluorescence from the {Mathematical expression} decays, we suppress the scattered laser light background count rate to 1 s -1 while maintaining a signal of 29000 s -1 with moderate saturation of the cooling transition. This scheme will be particularly useful for experiments where ions are trapped in close proximity to surfaces, such as the trap electrodes in microfabricated ion traps, which leads to high background scatter from the cooling beam. © 2011 Springer-Verlag.