• Ditscherlein, Ralf
• Leißner, Thomas
• Furat, Orkun
• Peuker, Urs A.
• Sygusch, Johanna
• Silva, Juliana Martins De Souza E.
• Langlard, Mathieu De
• Schmidt, Volker
• Rudolph, Martin

Abstract

<jats:p>The three-dimensional characterization of distributed particle properties in the micro- and nanometer range is essential to describe and understand highly specific separation processes in terms of selectivity and yield. Both performance measures play a decisive role in the development and improvement of modern functional materials. In this study, we mixed spherical glass particles (0.4–5.8<jats:italic>μ</jats:italic>m diameter) with glass fibers (diameter 10<jats:italic>μ</jats:italic>m, length 18–660<jats:italic>μ</jats:italic>m) to investigate a borderline case of maximum difference in the aspect ratio and a significant difference in the characteristic length to characterize the system over several size scales. We immobilized the particles within a wax matrix and created sample volumes suitable for computed tomographic (CT) measurements at two different magnification scales (X-ray micro- and nano-CT). Fiber diameter and length could be described well on the basis of the low-resolution micro-CT measurements on the entire sample volume. In contrast, the spherical particle system could only be described with sufficient accuracy by combining micro-CT with high-resolution nano-CT measurements on subvolumes of reduced sample size. We modeled the joint (bivariate) distribution of fiber length and diameter with a parametric copula as a basic example, which is equally suitable for more complex distributions of irregularly shaped particles. This enables us to capture the multidimensional correlation structure of particle systems with statistically representative quantities.</jats:p>

Topics

• impedance spectroscopy
• glass
• glass