First‐principles study of thermophysical properties of polymorphous YTaO4 ceramics

Yttrium tantalate ceramics with ferroelasticity are potential candidates for thermal barrier coating (TBC) ceramics. During the phase transition process, there are three main phases with monoclinic (I2/a), monoclinic‐prime (P2/a), and tetragonal structures (I41/a), and a comprehensive understanding...

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Bibliographic Details
Published in:Journal of the American Ceramic Society 2021-12, Vol.104 (12), p.6467-6480
Main Authors: Zhou, Yunxuan, Gan, Mengdi, Yu, Wei, Chong, Xiaoyu, Feng, Jing
Format: Article
Language:English
Subjects:
Bonding strength
Ceramic coatings
Ceramics
Ferroelasticity
first‐principles calculations
Mathematical analysis
Mechanical properties
Modulus of elasticity
Phase transitions
Principles
rare‐earth tantalates
structural ceramics
Tantalum
Temperature
Thermal barrier coatings
Thermal expansion
thermal properties
Thermodynamic properties
Thermophysical properties
ultra‐high temperature ceramics
Yttrium
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Summary:Yttrium tantalate ceramics with ferroelasticity are potential candidates for thermal barrier coating (TBC) ceramics. During the phase transition process, there are three main phases with monoclinic (I2/a), monoclinic‐prime (P2/a), and tetragonal structures (I41/a), and a comprehensive understanding of their thermophysical properties is required. In this study, the thermal and mechanical properties of polymorphous yttrium tantalate (YTaO4) ceramics are systematically investigated under finite temperature by performing first‐principles calculations combined with quasi‐harmonic approximation. The first‐principle study results show that the volume change from M' to T phase is 12.85 Å3 to 12.95 Å3 per atom, whereas the T to M is 12.95 Å3 to 12.84 Å3 per atom, and the change is less than 1%, showing that this process produces almost no volume change. However, the thermal expansion coefficients (TECs) and Young's modulus vary greatly, the TECs value of M YTaO4 is about 11.13 × 10−6 K−1, which is smaller than T YTaO4 as the value 12.01 × 10−6 K−1, and the Young's modulus values of M, M', and T phases are 140.34, 156.68, and 123.29 GPa, respectively. Lastly, the calculated O–Ta bond is stronger than the O–O and O–Y bonds according to the mean bond population and average bond length, resulting in a higher modulus. This work will not only expand the internal mechanism of the thermophysical properties of YTaO4, but also provides support for the design and application of TBC systems.
ISSN:0002-7820
1551-2916
DOI:10.1111/jace.18020