Tough and damage-tolerant monolithic zirconia ceramics with transformation-induced plasticity by grain-boundary segregation

Conventional ceria-stabilized tetragonal zirconia (Ce-TZP) with modest flexural strength has rarely been used as compared to yttria-stabilized zirconia, even though it has excellent hydrothermal stability and high toughness. Ce-TZP-based composites were recently developed, being tough and remarkably in combination with transformation-induced plasticity. However, distinct from the widely applied composite approach to improve the strength of Ce-TZP, in this study, a simpler and easily tailorable method was proposed by doping aliovalent oxides that are able to segregate at the zirconia-grain boundaries. 0.2-1 mol% divalent oxides with different cation size (Mg2+, Ca2+, Ba2+ and Sr2+) were selected to dope 10 mol% ceria-stabilized zirconia. CaO and MgO dopants were able to enter the tetragonal Ce-TZP lattice and showed a grain-boundary segregation effect, thereby tailoring the microstructure and transformation behavior. At a higher dopant concentration of 1 mol% MgO or CaO, the ceramics were strong but brittle with a typical elastic linear fracture behavior, whereas at a low dopant concentration of 0.1-0.2 mol% CaO or 0.2-0.4 mol% MgO doping, the ceramics deformed in-elastically to a certain degree without changing the Young's modulus. At the transition between both fracture behaviors, the best combination of toughness (>10 MPa m1/2), biaxial strength (>= 1200 MPa), reliability (Weibull modulus up to 30) and damage-tolerance was obtained. In-situ fracture testing revealed that transformation in such tough and deformable zirconia ceramics took place well before crack initiation with a large transformation zone of -100 mu m ahead of the crack tip having been formed before failure.

Automated summary

This study proposes a simpler and more controllable method to improve the mechanical properties of conventional ceria-stabilized tetragonal zirconia (Ce-TZP) by doping aliovalent oxides that can segregate at the zirconia-grain boundaries. It is found that doping with calcium and magnesium can change the microstructure and transformation behavior of the material, enabling ceramic materials to undergo inelastic deformation to a certain extent, thereby achieving the optimal combination of toughness, biaxial strength, and damage tolerance.