Abstract
YTaO4 and the relevant modification are considered to be a promising new thermal barrier coating. In this article, phase stability and mechanical properties of the monoclinic (M), monoclinic-prime (M′), and tetragonal (T) REMO4 (M = Ta, Nb) are systematically investigated from first-principles calculations method based on density functional theory (DFT). Our calculations show that M′-RETaO4 is the thermodynamically stable phase at low temperatures, but the stable phase is a monoclinic structure for RENbO4. Moreover, the calculated relative energies between M (or M′) and T phases are inversely proportional to the ionic radius of rare earth elements. It means that the phase transformation temperature of M′→T or M→T could decrease along with the increasing ionic radius of RE3+, which is consistent with the experimental results. Besides, our calculations exhibit that adding Nb into the M′-RETaO4 phase could induce phase transformation temperature of M′→M. Elastic coefficient is attained by means of the strain-energy method. According to the Voigt–Reuss–Hill approximation method, bulk modulus, shear modulus, Young’s modulus, and Poisson’s ratio of T, M, and M’ phases are obtained. The B/G criterion proposed by Pugh theory exhibits that T, M, and M’ phases are all ductile. The hardness of REMO4 (M = Ta, Nb) phases are predicted based on semi-empirical equations, which is consistent with the experimental data. Finally, the anisotropic mechanical properties of the REMO4 materials have been analyzed. The emerging understanding provides theoretical guidance for the related materials development.
Highlights
IntroductionYTaO4 and the relevant modification are extensively investigated and supposed to be promising thermal barrier coatings (TBCs) [2,3,4] due to high phase stability, good mechanical properties, and thermal conductivity
The rare-earth tantalate and niobates with the formula REMO4 (M = Ta, Nb) have attracted increasing attention due to their wide application, such as biomedicine, military technology, aerospace, remote sensing, and laser [1]
The electron-ion interactions were described through projector augmented wave (PAW) [13] and the exchange-correlation functional was constructed by the generalized gradient approximation (GGA) proposed by Perdew
Summary
YTaO4 and the relevant modification are extensively investigated and supposed to be promising thermal barrier coatings (TBCs) [2,3,4] due to high phase stability, good mechanical properties, and thermal conductivity. Because of a ferroelastic toughening mechanism similar to the familiar ZrO2 -8 mol%YO1.5 (8YSZ) materials, the high-temperature fracture toughness of YTaO4 is very well [5]. The high-temperature phase transition is a second-order and displacive transformation when the equilibrium tetragonal (T) transited to the monoclinic (M) YTaO4 phase [6]. Yttrium tantalate has more superior advantages than YSZ, it still has some shortcomings as a new thermal barrier coating. To improve the properties of the yttrium tantalate, doping and modifying are important
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