Positioning of the rf potential minimum line of a linear Paul trap with micrometer precision

TL;DR

This paper presents a precise method to control the position of the rf potential minimum line in a linear Paul trap by adjusting load capacitance, enabling micrometer accuracy without disturbing ion crystals.

Contribution

The authors introduce a novel technique for radial displacement of the rf field node in a linear Paul trap via load capacitance adjustment, improving precision and reducing crystal distortion.

Findings

Displacements of up to 100 micrometers achieved with micrometer precision.

No measurable distortion or excess heating of Coulomb crystals during displacement.

Technique applicable for microtrap architectures and ion cavity QED experiments.

Abstract

We demonstrate a general technique to achieve a precise radial displacement of the nodal line of the radiofrequency (rf) field in a linear Paul trap. The technique relies on selective adjustment of the load capacitance of the trap electrodes, achieved through the addition of capacitors to the basic resonant rf-circuit used to drive the trap. Displacements of up to 100 micrometer with micrometer precision are measured using a combination of fluorescence images of ion Coulomb crystals and coherent coupling of such crystals to a mode of an optical cavity. The displacements are made without measurable distortion of the shape or structure of the Coulomb crystals, as well as without introducing excess heating commonly associated with the radial displacement of crystals by adjustment through static potentials. We expect this technique to be of importance for future developments of microtrap architectures and ion-based cavity QED.