Analysis of nanometre sized aligned conical pores using SAXS

TL;DR

This study employs SAXS to quantitatively analyze the morphology of aligned conical nanopores in amorphous silicon dioxide and polycarbonate, developing new model fitting techniques for precise shape reconstruction.

Contribution

The paper introduces a novel SAXS analysis method with a model fitting approach for accurate, high-precision reconstruction of conical pore morphologies in thin films.

Findings

Validated a model fitting procedure for 2-D SAXS images.

Demonstrated the use of tilt series to minimize measurement errors.

Achieved unprecedented precision in cone morphology reconstruction.

Abstract

Small angle X-ray scattering (SAXS) was used to quantitatively study the morphology of aligned, mono-disperse conical etched ion tracks in thin films of amorphous silicon dioxide with aspect ratios of around 6:1, and in polycarbonate foils with aspect ratios of around 1000:1. This paper presents the measurement procedure and methods developed for the analysis of the scattering images and shows results obtained for the two material systems. To enable accurate parameter extraction from the data collected from conical scattering objects a model fitting the 2-D detector images was developed. The analysis involved fitting images from a sequence of measurements with different sample tilts to minimise errors which may have been introduced due to the experimental set-up. The model was validated by the exploitation of the geometric relationship between the sample tilt angle and the cone opening angle, to an angle observed in the features of the SAXS images. We also demonstrate that a fitting procedure for 1-D data extracted from the scattering images using a hard cylinder model can also be used to extract the cone size. The application of these techniques enables us to reconstruct the cone morphologies with unprecedented precision.