Dynamic recrystallization in a heavily alloyed PM γ+γ' nickel-based superalloy

R.I. Zainullin; R.V. Shakhov; S.K. Mukhtarov; V.M. Imayev

doi:10.48612/letters/2025-4-388-393

Dynamic recrystallization in a heavily alloyed PM γ+γ' nickel-based superalloy

R.I. Zainullin, R.V. Shakhov, S.K. Mukhtarov, V.M. Imayev show affiliations and emails

Received 14 November 2025; Accepted 26 November 2025;

Citation: R.I. Zainullin, R.V. Shakhov, S.K. Mukhtarov, V.M. Imayev. Dynamic recrystallization in a heavily alloyed PM γ+γ' nickel-based superalloy. Lett. Mater., 2025, 15(4) 388-393

BibTex https://doi.org/10.48612/letters/2025-4-388-393

Abstract

IPF (inverse pole figure) map obtained for the HIPed VV750P superalloy subjected compression at 1175°C, e= 1.39: low- and high-angle grain/interphase boundaries are indicated by white and black lines, respectively

Effect of isothermal hot compression at temperatures below the γ' solvus temperature on the development of dynamic recrystallization was studied in a powder metallurgy (PM) γ+γ' nickel-based superalloy VV750P (ВВ750П, Ni-9.9(Al, Ti, Nb)-33.7(Co, Cr, Mo, W, Hf)-0.075(C, B) (wt.%)). This superalloy is heavily alloyed and has a high γ' solvus temperature (Ts =1190°C). In the initial HIPed condition, the average γ grain size was d ≈ 29 µm and volume fraction of γ' (Ni3(Al, Ti, Nb)) phase about 70 %. Small cylindrical samples were prepared from the HIPed material and subjected to isothermal single-stage compression in the temperature range of 1125 –1175°C ((Ts−65) – (Ts−15), where Ts is the γ' solvus temperature) with an initial strain rate έ =10−2 s−1 to an engineering strain ε = 75 %. The temperature / strain rate conditions were chosen on basis of previously performed studies on other PM nickel-based superalloys such as EP741NP (ЭП741НП) and VV751P (ВВ751П). In contrast to previously performed works, the present investigation aimed at achieving completely recrystallized and fine-grained structure without using annealing after HIP and intermediate recrystallization annealing. Hot compression at 1125 –1175°C led to development of dynamic recrystallization. However, recrystallization kinetics significantly depended on deformation temperature. The fastest kinetics of recrystallization was reached during compression at 1175°C (Ts−15) that is only slightly below the γ' solvus temperature. In contrast to compression at 1125 and 1150°C, hot compression at 1175°C resulted in a complete disappearance of coarse prior γ grains and formation of completely recrystallized and fine-grained structure. Thus, single-stage isothermal hot forging of HIPed PM superalloy at a slightly subsolvus temperature without additional annealing can be considered as an alternative processing route instead of two- or three-stage forging at subsolvus temperatures with intermediate annealing.

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Funding

1. Russian Science Foundation - 25-29-00806

Dynamic recrystallization in a heavily alloyed PM γ+γ' nickel-based superalloy

Abstract

References (24)

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