Phase Evolution and Thermal Expansion Behavior of a γ′ Precipitated Ni-Based Superalloy by Synchrotron X-Ray Diffraction

doi:10.1007/s40195-021-01321-2

Abstract

Abstract:

The phase evolution and thermal expansion behavior in superalloy during heating play an essential role in controlling the size and distribution of precipitates, as well as optimizing thermomechanical properties. Synchrotron X-ray diffraction is able to go through the interior of sample and can be carried out with in situ environment, and thus, it can obtain more statistics information in real time comparing with traditional methods, such as electron and optical microscopies. In this study, in situ heating synchrotron X-ray diffraction was carried out to study the phase evolution in a typical γ′ phase precipitation strengthened Ni-based superalloy, Waspaloy, from 29 to 1050 °C. The γ′, γ, M₂₃C₆ and MC phases, including their lattice parameters, misfits, dissolution behavior and thermal expansion coefficients, were mainly investigated. The γ′ phase and M₂₃C₆ carbides appeared obvious dissolution during heating and re-precipitated when the temperature dropped to room temperature. Combining with the microscopy results, we can indicate that the dissolution of M₂₃C₆ leads to the growth of grain and γ′ phase cannot be completely dissolved for the short holding time above the solution temperature. Besides, the coefficients of thermal expansions of all the phases are calculated and fitted as polynomials.

Key words: Superalloy, Waspaloy, Lattice misfit, Coefficients of thermal expansion, X-ray diffraction, Synchrotron radiation

Zhiran Yan, Qing Tan, Hua Huang, Hailong Qin, Yi Rong, Zhongnan Bi, Runguang Li, Yang Ren, Yandong Wang. Phase Evolution and Thermal Expansion Behavior of a γ′ Precipitated Ni-Based Superalloy by Synchrotron X-Ray Diffraction[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(1): 93-102.

Figures/Tables 12

Fig. 1 a Schematic of X-ray diffraction experiment setup, b representative X-ray diffraction patterns (half of an image plate) for Waspaloy under 29 and 1050 °C

Fig. 2 X-ray diffraction data: a integrated intensity throughout the heating experiment, b 1-D diffraction profiles corresponding to different temperatures: room temperature before and after heating, 500 and 1050 °C

Fig. 3 Integrated diffraction intensity of γ′ superlattice reflections [(100), (110), (210) and (211)] of Waspaloy during heating

Fig. 4 Micrographs of Waspaloy a, b before, c, d after the in situ heating test

Fig. 5 a Lattice parameters of γ and γ′ phases and b lattice misfit evolution during in situ heating

Fig. 6 Full width at half maximum (FWHM) evolution of γ and γ′ phases during heating

Fig. 7 Integrated diffraction intensity evolution of M23C6 (440) and MC (220) reflection with increasing temperature

Fig. 8 Energy-dispersive spectroscopy (EDS) elemental mapping images of a M23C6 b MC

Fig. 9 Grain distribution a before and b after in situ heating

Fig. 10 Coefficients of thermal expansion [α(T)] of γ and γ′ phases under different temperatures

Fig. 11 a Lattice constant and b coefficients of thermal expansion [α(T)] of M23C6 and MC phases under different temperatures

Fig. 12 Coefficients of thermal expansion [α(T)] obtained in this study, including the mean CTE calculated based on Eq. 11 (?Eq. 11) and the mean lattice spacing (?mean d-spacing), as well as reported data (αHidnert) [30]

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