Beyond the Average: Spatial and Temporal Fluctuations in Oxide Glass-Forming Systems

Controlling Thermal Conductivity of Amorphous SiOx Films through Structural Engineering Utilizing Single Crystal Substrate Surfaces

Development of thin films with low thermal conductivity (κ) and high dielectric breakdown strength is essential to engineer insulating materials for electronics packaging and other application domains, such as power electronics. Silica glass (SiO2) has extremely high dielectric breakdown strength but a relatively high κ compared to multicomponent silicate glasses. This study reveals that a large and systematic decrease in κ can be obtained by shorter intermediate ordering distances controlled by stronger constraints from the substrate surface atoms. The largest effect on κ is observed for SiOx films on Si substrates, which can reach one-third of the bulk value. The change in ordering is observable by the shift of the main halo measured by grazing incidence X-ray total scattering. The improved understanding of the κ of SiOx films presented herein could enable new materials design for electronic devices including wide-bandgap semiconductors.

Crystallization inhibition in molecular liquids by polymers above the overlap concentration (c*): Delay of the first nucleation event

Low concentration polymer additives can significantly alter crystal growth kinetics of molecular liquids and glasses. However, the effect of polymer concentration on nucleation kinetics remains poorly understood. Based on an experimentally determined first nucleation time (time to form the first critical nucleus, t0), we show that the polymer overlap concentration, c*, where polymer coils in the molecular liquid start to overlap with each other, is a critical polymer concentration for efficient inhibition of crystallization of a molecular liquid. The value of t0 is approximately equal to that of the neat molecular liquid when the polymer concentration, c, is below c*, but increases significantly when c > c*. This finding is relevant for effective polymer screening and performance prediction of engineered multicomponent amorphous materials, particularly pharmaceutical amorphous solid dispersions.

Kinetics of physical aging of a silicate glass following temperature up- and down-jumps

In this article, we investigate the structural relaxation of lithium silicate glass during isothermal physical aging by monitoring the temporal evolution of its refractive index and enthalpy following relatively large (10-40 °C) up- and down-jumps in temperature. The Kohlrausch-Williams-Watts function aptly describes the up- and down-jump data when analyzed separately. For temperature down-jumps, the glass exhibits a typical stretched exponential kinetic behavior with the non-exponentiality parameter β < 1, whereas up-jumps show a compressed exponential behavior (β > 1). We analyzed these datasets using the non-exponential and non-linear Tool-Narayanaswamy-Moynihan (TNM) model, aiming to provide a comprehensive description of the primary or α-relaxation of the glass. This model described both up- and down-jump datasets using a single value of β ≤ 1. However, the standard TNM model exhibited a progressively reduced capacity to describe the data for larger temperature jumps, which is likely a manifestation of the temperature dependence of the non-exponentiality or non-linearity of the relaxation process. We hypothesize that the compressed exponential relaxation kinetics observed for temperature up-jumps stems from a nucleation-growth-percolation-based evolution on the dynamically mobile regions within the structure, leading to a self-acceleration of the dynamics. On the other hand, temperature down-jumps result in self-retardation, as the slow-relaxing denser regions percolate in the structure to give rise to a stretched exponential behavior.

The Crystallization of Disordered Materials under Shock Is Governed by Their Network Topology

When the shock load is applied, materials experience incredibly high temperature and pressure conditions on picosecond timescales, usually accompanied by remarkable physical or chemical phenomena. Understanding the underlying physics that governs the kinetics of shocked materials is of great importance for both physics and materials science. Here, combining experiment and large-scale molecular dynamics simulation, the ultrafast nanoscale crystal nucleation process in shocked soda-lime silicate glass is investigated. By adopting topological constraints theory, this study finds that the propensity of nucleation is governed by the connectivity of the atomic network. The densification of local networks, which appears once the crystal starts to grow, results in the underconstrained shell around the crystal and prevents further crystallization. These results shed light on the nanoscale crystallization mechanism of shocked materials from the viewpoint of topological constraint theory.