Litcius/Paper detail

Oxygen vacancy-induced strengthening and toughening in (K,Na)NbO3-based piezoceramics revealed via nanoindentation

Zhidong Zhang, Bin Yang, Longyu Chen, Zaoli Zhang, Jinming Guo, Zaoli Zhang, Jinming Guo

2025Nature Communications19 citationsDOIOpen Access PDF

Abstract

Dislocations are emerging as a pivotal factor for tailoring ceramics’ functional and mechanical properties. The introduction of point defects, notably oxygen vacancies, is unavoidable during the conventional sintering process in polycrystalline ceramics. Understanding the interplay between dislocations and oxygen vacancies is necessary for its profound implications. This work implements an innovative approach to regulate the dislocation-based incipient plasticity and creep behavior in (K0.5Na0.5)NbO3-based ceramics through oxygen vacancy engineering via CuO “hard” doping. Nanoindentation pop-in tests reveal that increasing oxygen vacancy concentrations significantly promotes the nucleation and activation of dislocations. Theoretical calculations based on density functional theory further corroborate that oxygen vacancies contribute to a decrease in Peierls stress and total misfit energy, facilitating dislocation nucleation and activation. Nanoindentation hardness and creep behavior demonstrate that oxygen vacancy impedes dislocation mobility due to solute strengthening and pinning effects. The effect of oxygen vacancies is elucidated through diverse mechanisms related to the interaction between dislocations and oxygen vacancies at different stages. This oxygen vacancy-induced strengthening and toughening strategy displays a significant potential to improve the mechanical properties of piezoelectric ceramics, while still maintaining high electrical performance. The study reveals that oxygen vacancies significantly enhance dislocation nucleation and activation, while strengthening the (K, Na)NbO3-based piezoceramics through solute strengthening and pinning effect between oxygen vacancies and dislocations.

Topics & Concepts

NanoindentationTougheningMaterials scienceVacancy defectOxygenPiezoelectricityChemical engineeringComposite materialChemistryCrystallographyToughnessEngineeringOrganic chemistryFerroelectric and Piezoelectric MaterialsAdvanced ceramic materials synthesisMetal and Thin Film Mechanics