| METALS AND METAL MATRIX COMPOSITES |
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| Research Progress in Dissolution Behavior and Kinetics of γ′ Precipitate in Nickel-based Powder Metallurgy Superalloys |
| WANG Jie, HUANG Hailiang*, ZHOU Yazhou, ZHANG Hua, RUAN Jingjing, ZHOU Xin, ZHANG Shangzhou, JIANG Liang
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| Institute for Advanced Studies in Precision Materials, Yantai University, Yantai 264010, Shandong, China |
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Abstract In order to meet the requirements of high performance and high thermal efficiency of aeroengine, the gradual increase of alloying elements in nickel-based powder metallurgy (PM) superalloys leads to high deformation resistance, poor thermoplasticity and narrow hot working window of the PM superalloys, which restricts the preparation and application of the alloy. The γ′ precipitate with high volume fraction in PM superalloys plays a role in microstructure control during hot working. The evolution of γ′ precipitates affects the hot deformation behavior and hot workability of the PM superalloys. Understanding the evolution law of γ′ precipitates is of great significance to control the microstructural evolution and optimize the hot working process of superalloys. In this paper, the dissolution of γ′ precipitates in the hot working process of nickel-based PM superalloys is discussed. The research works on the dissolution behaviors of γ′ precipitates, influence factors and prediction models are reviewed. At pre-sent, the dissolution mechanism of precipitates in high volume fraction multi-particle system is not clear, whether there is splitting and agglomeration behavior in the dissolution process of γ′ precipitate and its influence mechanism, the interaction mechanism between dislocation and γ′ precipitate in the thermal deformation process and the dissolution kinetics of γ′ precipitate need to be further studied.
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Published: 10 November 2023
Online: 2023-11-10
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| Fund:National Key R & D Program of China(2021YFB3700401), National Natural Science Foundation of China (52201049) and Talent Training Program for Shandong Province Higher Educational Youth Innovative Teams (2021). |
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2023, Vol. 37 
