Quantitative study of the microstructure evolution along the thickness direction in the nickel-based single crystal superalloy DD6 at 1323 K thermal exposure

“…The shape of the nickel-based single crystal hollow turbine blades is complex, which leads to a complicated process of directional solidification of single crystal blades [14,15]. The complexity of the blade shape and the solidification process makes the uneven distribution of the microstructure inevitably formed during the production process [16,17]. The structure of the material determines the performance of the material, and the distribution of the γ' phase structure of the single crystal superalloy has a significant effect on the high temperature performance of the single crystal blade.…”

Quantitative Characterization of the γ’ Phase Distribution in the Large-Scale Area of the Second-Generation Nickel-Based Single Crystal Blade DD5

“…The shape of the nickel-based single crystal hollow turbine blades is complex, which leads to a complicated process of directional solidification of single crystal blades [14,15]. The complexity of the blade shape and the solidification process makes the uneven distribution of the microstructure inevitably formed during the production process [16,17]. The structure of the material determines the performance of the material, and the distribution of the γ' phase structure of the single crystal superalloy has a significant effect on the high temperature performance of the single crystal blade.…”

Quantitative Characterization of the γ’ Phase Distribution in the Large-Scale Area of the Second-Generation Nickel-Based Single Crystal Blade DD5

Comparative study of temperature-dependent oxidation and interdiffusion behavior on NiCoCrAlYHf-coated nickel-based single-crystal superalloys

Environmental Effects on the Creep Response of Thin-Walled Ni-Based Single Crystal Superalloys