Xiao Mei Zeng scite author profile

Shape memory ceramics that exhibit repeatable superelastic deformation are of considerable significance for possible energy damping and micro-actuation applications, and the present work aims to further establish the structural conditions required to avoid fracture in these brittle materials. Spray dried micro-scale superelastic ceramic particles with a variety of grain structures were produced, ranging from single crystal to oligocrystal to polycrystalline particles. Micro-compression experiments showed that whereas polycrystalline samples fracture upon loading, oligocrystal and single crystal particles can exhibit cyclic superelasticity, the latter particles achieving highly reproducible superelasticity to over one hundred cycles with particle compressions up to 3.8% and dissipated energy up to 20-40 MJ/m 3 per cycle. The mechanisms of structural evolution and fracture during cyclic loading are also explored.

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Microstructure, crystallization and shape memory behavior of titania and yttria co-doped zirconia

Zeng

Schuh

et al. 2016

Journal of the European Ceramic Society

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Synthesis of monodisperse CeO₂–ZrO₂ particles exhibiting cyclic superelasticity over hundreds of cycles

Zeng

et al. 2017

J Am Ceram Soc

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Nano‐ and microscale CeO2–ZrO2 (CZ) shape memory ceramics are promising materials for smart micro‐electro‐mechanical systems (MEMS), sensing, actuation and energy damping applications, but the processing science for scalable production of such small volume ceramics has not yet been established. Herein, we report a modified sol‐gel method to synthesize highly monodisperse spherical CZ particles with diameters in the range of ~0.8‐3.0 μm. Synchrotron X‐ray micro‐diffraction (μSXRD) confirmed that most of the particles are single crystal after annealing at 1450°C. Having a monocrystalline structure and a small specimen length scale, the particles exhibit significantly enhanced shape memory and superelasticity properties with up to ~4.7% compression being completely recoverable. Highly reproducible superelasticity through over five hundred strain cycles, with dissipated energy up to ~40 MJ/m3 per cycle, is achieved in the CZ particles containing 16 mol% ceria. This cycling capability is enhanced by ten times compared with our first demonstration using micropillars (only 50 cycles in Lai et al, Science, 2013, 341, 1505). Furthermore, the effects of cycling and testing temperature (in 25°C‐400°C) on superelasticity have been investigated.

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Xiao Mei Zeng

Crystal orientation dependence of the stress-induced martensitic transformation in zirconia-based shape memory ceramics

Size effects and shape memory properties in ZrO2 ceramic micro- and nano-pillars

Superelasticity in micro-scale shape memory ceramic particles

Microstructure, crystallization and shape memory behavior of titania and yttria co-doped zirconia

Synthesis of monodisperse CeO₂–ZrO₂ particles exhibiting cyclic superelasticity over hundreds of cycles

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Xiao Mei Zeng

Crystal orientation dependence of the stress-induced martensitic transformation in zirconia-based shape memory ceramics

Size effects and shape memory properties in ZrO2 ceramic micro- and nano-pillars

Superelasticity in micro-scale shape memory ceramic particles

Microstructure, crystallization and shape memory behavior of titania and yttria co-doped zirconia

Synthesis of monodisperse CeO2–ZrO2 particles exhibiting cyclic superelasticity over hundreds of cycles

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Synthesis of monodisperse CeO₂–ZrO₂ particles exhibiting cyclic superelasticity over hundreds of cycles