Magic ratio of window width to grating period for Van der Waals potential measurements using material gratings

TL;DR

This paper introduces a method to precisely measure Van der Waals potential strength using a specific 'magic' open-fraction or angle of nano-fabricated gratings, enhancing measurement accuracy for atom-surface interactions.

Contribution

The study demonstrates a novel 'magic' open-fraction and angle technique that improves the precision of $C_3$ measurements without needing separate grating width measurements.

Findings

Achieved precise $C_3$ values for Na and SiN$_x$ surfaces.

Detected changes in $C_3$ due to thin metal coatings.

Validated the method's effectiveness with different grating configurations.

Abstract

We report improved precision measurements of the Van der Waals potential strength ($C_3$) for Na atoms and a silicon-nitride (SiN$_x$) surface. We studied diffraction from nano-fabricated gratings with a particular "magic" open-fraction that allows us to determine $C_3$ without the need for separate measurements of the width of the grating openings. Therefore, finding the magic open-fraction improves the precision of $C_3$ measurements. The same effect is demonstrated for a grating with an arbitrary open-fraction by rotating it to a particular "magic" angle, yielding $C_3=3.42\pm 0.19 \textrm{eV} \mathring{\textrm{A}}^3$ for Na and a SiN$_x$ surface. This precision is sufficient to detect a change in $C_3$ due to a thin metal coating on the grating surface. We discuss the contribution to $C_3$ of core electrons and edge effects.