Reducing detrimental electrostatic effects in Casimir-force measurements and Casimir-force-based microdevices

TL;DR

This study demonstrates that in situ Ar-ion cleaning of surfaces significantly reduces electrostatic effects, enabling more precise Casimir force measurements and improving the performance of Casimir-based microdevices.

Contribution

The paper introduces an effective in situ Ar-ion cleaning method to minimize electrostatic forces in Casimir experiments and microdevices.

Findings

Residual potential difference decreased by up to an order of magnitude after cleaning.

Electrostatic effects became almost independent of separation distance.

Experimental results aligned well with Lifshitz theory predictions.

Abstract

It is well known that residual electrostatic forces create significant difficulties to precise measurements of the Casimir force and to wide use of Casimir-operated microdevices. We experimentally demonstrate that with the help of Ar-ion cleaning of the surfaces it is possible to make electrostatic effects negligibly small as compared to the Casimir interaction. Our experimental setup consists of the dynamic atomic force microscope supplemented with an Ar-ion gun and argon reservoir. The residual potential difference between the Au-coated surfaces of a sphere and a plate was measured both before and after the in situ Ar-ion cleaning. It is shown that this cleaning decreases the magnitude of the residual potential by up to an order of magnitude and makes it almost independent on separation. The gradient of the Casimir force was measured using ordinary samples subjected to the Ar-ion cleaning. The obtained results are shown to be in good agreement with both previous precision measurements using the specially selected samples and with theoretical predictions of the Lifshitz theory. The conclusion is made that the suggested method of in situ Ar-ion cleaning is effective in reducing the electrostatic effects and therefore is a great resource for experiments on measuring the Casimir interaction and for Casimir-operated microdevices.