X-ray powder diffraction of crystalline phases in phosphate bioglass ceramics

Schulz, C.; Miehe, G.; Fueß, H.; Wange, P.; Götz, W.

doi:10.1524/zkri.1994.209.3.249

Cited by 5 publications

(1 citation statement)

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“…Additionally, F-containing materials display enhanced electrochemical properties for use in Li-ion cells due to the strong inductive potential of F with phosphates, for example, in lithium fluorophosphate glasses/glass ceramics [ 27 ]. As a consequence of their collective impact on the physical and chemical characteristics of glass networks, glasses and glass ceramics containing both Ti and F are of increasing interest to the community, especially with respect to controlling crystallization kinetics, microstructure, and subsequent material properties [ 19 , 20 , 25 , 26 , 28 , 29 , 30 , 31 ].…”

Section: Introductionmentioning

confidence: 99%

State of the Art Review for Titanium Fluorine Glasses and Glass Ceramics

Kettlewell,

Boyd

2024

Materials

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Titanium (Ti) and fluorine (F) have the potential to provide a variety of desirable physical, chemical, mechanical, and biological properties applicable to a broad range of indications. Consequently, Ti- and F-containing glasses and glass ceramics are currently under investigation for use in nuclear, optical, electrochemical, dental, and industrial fields. Accordingly, significant interest exists with respect to understanding the individual and interaction effects that these elements have on material structure and properties to support the accelerated design, development, and deployment of these materials. This review aims to serve as a foundational reference across multiple disciplines, highlighting the fundamental properties and versatility of Ti- and F-containing glasses and glass ceramics. By consolidating our current knowledge of these materials, this broad overview will identify areas in which we can further our understanding to support the a priori prediction and effective design of these systems. Finally, this paper will introduce the potential to improve material design by integrating experimentation, modelling, and computational approaches in a manner commensurate with the principles of the Materials Genome Initiative.

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