Strengthening mechanisms of carbon in modified nickel-based superalloy Nimonic 80A

• Published in: Materials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 528; no. 13; pp. 4600 - 4607
• Main Authors: Xu, Yulai, Jin, Qiumin, Xiao, Xueshan, Cao, Xiuli, Jia, Guoqing, Zhu, Yuemei, Yin, Huaijin
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier B.V 25.05.2011; Elsevier
• Subjects: Carbides; Carbon; Carbon content; Cross-disciplinary physics: materials science; rheology; Dislocations; Exact sciences and technology; Grain boundaries; Materials science; Microstructures; Misfit; Nickel base alloys; Nickel-based superalloy; Phases; Physics; Precipitates; Precipitation; Scanning electron microscopy; Solid solution, precipitation, and dispersion hardening; aging; Strengthening; Strengthening mechanisms; Superalloys; Treatment of materials and its effects on microstructure and properties; Misfit; Nickel-based superalloy; Microstructures; Carbon; Strengthening mechanisms; Nickel base alloys; Scanning electron microscopy; Strengthening; XRD; Lattice parameters; Dispersive spectrometry; Superalloys; Precipitation hardening; Optical microscopy; Transmission electron microscopy; Carbon content; Microstructure; Transition element alloys
• ISSN: 0921-5093; 1873-4936
• DOI: 10.1016/j.msea.2011.02.072

► Misfit δ between γ′ and γ phases increased with the increase of carbon content. ► Cr 23C 6 has an orientation relationship with the γ matrix for the 0.10%C alloy. ► Cr 23C 6 at grain boundary enhance the grain boundary strengthening. ► Dislocation networks and precipitate strengthening benefit stress-rupture properties. Nickel-based superalloy Nimonic 80A with various carbon contents has been developed. Various strengthening mechanisms of carbon were analyzed by optical microscope, X-ray diffraction, scanning electron microscope equipped with energy dispersive spectroscopy and transmission electron microscope. Detailed microstructural analysis revealed that with the increase of carbon content from 0.01% to 0.10%, both the lattice parameters of γ′ and γ phases decreased, and the misfit δ between the coherent γ′ and γ phases increased slightly from 0.289% to 0.317% after full heat treatment at 1070 °C/8 h, A.C. + 700 °C/16 h, A.C. The diameter of spherical γ′ phase decreased from 22.24 nm of 0.01%C alloy to less than 15.76 nm of 0.06%C and 0.10%C alloys. Cr 23C 6 carbide precipitated at the grain boundary in the alloys with carbon content higher than 0.06%, and when carbon content increased to 0.10%, Cr 23C 6 carbide had an orientation relationship with the γ matrix: [ 00 1 ¯ ] Cr 23C 6 [ 00 1 ¯ ] γ   matrix   and ( 100 )   C r 23 C 6 (1 0 0) γ matrix, which can enforce the grain boundary strength. The growth of room temperature tensile strength with the increase of carbon content was primarily due to the coherent strain strengthening and the precipitate strengthening of Cr 23C 6 carbide. After stress-rupture test at 750 °C/310 MPa, the misfit δ increased from 0.182% to 0.237% with the increase of carbon content, but the values were lower than those after full heat treatment. The precipitate of blocky Cr 23C 6 in 0.10%C alloy tended to become spherical and dislocation lines were found in the γ matrix channels between γ′ phases, the combination of the dislocation strengthening and precipitate strengthening of Cr 23C 6 carbide at grain boundary was beneficial to the stress-rupture properties.