Your search keyword '"Wilke, Stephen K."' showing total 2 results

1. Octahedral oxide glass network in ambient pressure neodymium titanate.

Author

Wilke, Stephen K., Alderman, Oliver L. G., Benmore, Chris J., Neuefeind, Jörg, and Weber, Richard

Subjects

*DISTRIBUTION (Probability theory), *OPTICAL glass, *NEUTRON diffraction, *ATOMIC structure, *GLASS, *NEODYMIUM compounds, *TITANATES

Abstract

Rare-earth titanates form very fragile liquids that can be made into glasses with useful optical properties. We investigate the atomic structure of 83TiO2-17Nd2O3 glass using pair distribution function (PDF) analysis of X-ray and neutron diffraction with double isotope substitutions for both Ti and Nd. Six total structure factors are analyzed (5 neutron + 1 X-ray) to obtain complementary sensitivities to O and Ti/Nd scattering, and an empirical potential structure refinement (EPSR) provides a structural model consistent with the experimental measurements. Glass density is estimated as 4.72(13) g cm−3, consistent with direct measurements. The EPSR model indicates nearest neighbor interactions for Ti-O at r ¯ TiO = 1.984(11) Å with coordination of n TiO = 5.72(6) and for Nd-O at r ¯ NdO = 2.598(22) Å with coordination of n NdO = 7.70(26), in reasonable agreement with neutron first order difference functions for Ti and Nd. The titanate glass network comprises a mixture of distorted Ti-O5 and Ti-O6 polyhedra connected via 71% corner-sharing and 23% edge-sharing. The O-Ti coordination environments include 15% nonbridging O-Ti1, 51% bridging O-Ti2, and 32% tricluster O-Ti3. This structure is highly unusual for oxide glasses melt-quenched at ambient pressure, as it consists of Ti-Ox predominantly in octahedral (with nearly no tetrahedral) coordination. [ABSTRACT FROM AUTHOR]

Published

2022

2. Phase separation in mullite-composition glass.

Author

Wilke, Stephen K., Benmore, Chris J., Ilavsky, Jan, Youngman, Randall E., Rezikyan, Aram, Carson, Michael P., Menon, Vrishank, and Weber, Richard

Subjects

*PHASE separation, *X-ray scattering, *GLASS, *PLANETARY science, *SUPERCOOLING, *POLYMERIZATION

Abstract

Aluminosilicates (AS) are ubiquitous in ceramics, geology, and planetary science, and their glassy forms underpin vital technologies used in displays, waveguides, and lasers. In spite of this, the nonequilibrium behavior of the prototypical AS compound, mullite (40SiO2-60Al2O3, or AS60), is not well understood. By deeply supercooling mullite-composition liquid via aerodynamic levitation, we observe metastable liquid–liquid unmixing that yields a transparent two-phase glass, comprising a nanoscale mixture of AS7 and AS62. Extrapolations from X-ray scattering measurements show the AS7 phase is similar to vitreous SiO2 with a few Al species substituted for Si. The AS62 phase is built from a highly polymerized network of 4-, 5-, and 6-coordinated AlOx polyhedra. Polymerization of the AS62 network and the composite morphology provide essential mechanisms for toughening the glass. [ABSTRACT FROM AUTHOR]

Published

2022