TY  - EJOU
AU  - Fang, Zhou 
AU  - Zhong, Jiaqi 
AU  - Luo, Jun 
AU  - Sun, Yuanzun 

TI  - Phase Field Study of Ferroelastic Toughening Mechanisms of Polycrystalline t<sup>′</sup>-YSZ
T2  - Computer Modeling in Engineering \& Sciences

PY  - 
VL  - 
IS  - 
SN  - 1526-1506

AB  - The t<sup>′</sup> phase of yttria-stabilized zirconia (t<sup>′</sup>-YSZ) is the most extensively used top coat material in thermal barrier coatings (TBCs). Its relatively high fracture toughness is among the most important factors that enable t<sup>′</sup>-YSZ to stand out from other candidate ceramics. Unveiling the toughening mechanisms of t<sup>′</sup>-YSZ is conducive to the development of next-generation top-coat materials. In this paper, a coupled phase field model is proposed to study crack growth and domain evolution in polycrystalline t<sup>′</sup>-YSZ. Two distinct polycrystal microstructures are considered to investigate the impact of the initial domain structure on the toughening behavior. In Polycrystal I, each grain consists of a single domain of the t<sup>′</sup> phase. In Polycrystal II, the c-t<sup>′</sup> phase transformation gives rise to a twinned domain configuration. A unified phase field model is proposed to simulate the coupled process of crack propagation and domain evolution within both polycrystals. The localized toughening effect resulting from domain switching on crack advancement is characterized using the energy dissipation rate. Numerical findings reveal that the interplay between fracturing and domain evolution causes the crack to follow tortuous paths in both types of polycrystals, potentially enhancing the overall fracture toughness. The domain reorientation enhances the local crack growth resistance in both materials, though the domain evolution characteristics are distinctly different. The effects of domain evolution and the polycrystal microstructure on the crack growth behavior and the local toughening effect are systematically discussed. The findings reported in this paper offer valuable insights into the fracture toughening mechanisms of t<sup>′</sup>-YSZ ceramics. The phase field approach developed in the paper provides a powerful numerical framework for evaluating the fracture toughness of ferroelastic materials.
KW  - Fracture toughness; yttria stabilized zirconia; polycrystal; domain switching; phase field method

DO  - 10.32604/cmes.2026.081333