Litcius/Paper detail

Borrowed dislocations for ductility in ceramics

Limin Dong, Jie Zhang, Yizhuang Li, Yixuan Gao, M. Wang, Mingxin Huang, Jinshu Wang, Kexin Chen

2024Science142 citationsDOI

Abstract

The inherent brittleness of ceramics, primarily due to restricted atomic motions from rigid ionic or covalent bonded structures, is a persistent challenge. This characteristic hinders dislocation nucleation in ceramics, thereby impeding the enhancement of plasticity through a dislocation-engineering strategy commonly used in metals. Finding a strategy that continuously generates dislocations within ceramics may enhance plasticity. Here, we propose a "borrowing-dislocations" strategy that uses a tailored interfacial structure with well-ordered bonds. Such an approach enables ceramics to have greatly improved tensile ductility by mobilizing a considerable number of dislocations in ceramic borrowed from metal through the interface, thereby overcoming the challenge associated with direct dislocation nucleation within ceramics. This strategy provides a way to enhance tensile ductility in ceramics.

Topics & Concepts

Ductility (Earth science)CeramicMaterials scienceComposite materialCreepAdvanced ceramic materials synthesisAdvanced materials and compositesFerroelectric and Piezoelectric Materials