High-throughput assessment of Nb, Co, Ti, and Al effects on microstructure and mechanical properties in wrought nickel-based superalloys

Haoyan Meng , Jin Huang , Tianhao Zhao , Xiaoyu Zhang , Yang Tong , Jinglong Qu , Weidong Li , Liang Jiang , Fanchao Meng , Shuying Chen

Materials Genome Engineering Advances ›› 2025, Vol. 3 ›› Issue (3) : e70002

PDF
Materials Genome Engineering Advances ›› 2025, Vol. 3 ›› Issue (3) : e70002 DOI: 10.1002/mgea.70002
RESEARCH ARTICLE

High-throughput assessment of Nb, Co, Ti, and Al effects on microstructure and mechanical properties in wrought nickel-based superalloys

Author information +
History +
PDF

Abstract

The influence of Nb, Co, Ti, and Al on the microstructural evolution and mechanical properties of GH4061 superalloy was simultaneously investigated using diffusion multiple techniques combined with double aging heat treatment. Co exhibited the highest penetration depth with monotonic concentration decrease, significantly inhibiting the formation of needle-like δ phase and reduced the precipitation size of the γ′ phase. Nb diffusion formed distinct layers with clear interfaces, promoting substantial γ′′ phase precipitation, while simultaneously enhancing hardness through solid solution strengthening. Ti and Al diffusion generated substantial diffusion layers containing Ti-Ni enriched needle-like η phases and enhanced γ′ phase growth, characterized by increased size and volume fraction compared to the base alloy. In contrast to the base alloy, this diffusion layer was devoid of phases enriched with Nb. Mechanical property analysis demonstrated that high concentrations of Nb, Al, and Ti enhanced alloy hardness through various strengthening mechanisms, whereas increased Co content diminished the size of the γ′ phase at the interface, resulting in reduced hardness. This high-throughput experimental approach significantly reduced experimental workload while enabling detailed analysis of varying element concentrations on microstructure and properties.

Keywords

alloy elements effect / diffusion multiple / GH4061 superalloys / microstructure characterization

Cite this article

Download citation ▾
Haoyan Meng, Jin Huang, Tianhao Zhao, Xiaoyu Zhang, Yang Tong, Jinglong Qu, Weidong Li, Liang Jiang, Fanchao Meng, Shuying Chen. High-throughput assessment of Nb, Co, Ti, and Al effects on microstructure and mechanical properties in wrought nickel-based superalloys. Materials Genome Engineering Advances, 2025, 3(3): e70002 DOI:10.1002/mgea.70002

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Geddes B, Leon H, Huang X. Superalloys: Alloying and Performance. ASM International; 2010.
[2]

Donachie MJ, Donachie SJ. Superalloys: A Technical Guide. ASM international; 2002.
[3]

Yu Q. Influences of C and Mg on microstructures and mechanical properties of a nickel base superalloy. J Aeronautical Mater. 2006; 26: 11-13.
[4]

Fan Q, Liu HW. Effect of carbon contents on the tensile properties and creep life of K536 superalloy. Res Metallic Mater. 2011; 4: 12-17.
[5]

Tian N, Tian SG, Yu HC, et al. Configuration evolution of carbides and its influence on creep property of nickel-based superalloy. Chin J Nonferrous Metals. 2019; 7: 1427-1436.
[6]

Liang SZ, Liao JY, Xie CH, et al. The effect of heating on the carbides of H21 alloy. Mater Mech Eng. 2002; 12: 42-44.
[7]

Zhang XY, Wang ZT, Cheng M, et al. Carbides precipitation and its effect on structure of superalloy IN690. J Shenyang Ligong Univ. 2013; 4: 64-67.
[8]

Yang JX, Wei W, Liu L, et al. Primary carbides and its strengthening roles in K465 and K492 superalloy. Rare Metal Mater Eng. 2016; 4: 975-978.
[9]

Hu PP, Chen JY, Feng Q, et al. Effects of Mo on microstructure and stress-rupture property of Ni-based single crystal superalloys. Chin J Nonferrous Metals. 2011; 2: 332-340.
[10]

Ma WY, Han YG, Li SS, et al. Effect of content on the microstructure and stress rupture of a Ni base single crystal superalloy. Acta Metall Sin. 2006; 11: 1191-1196.
[11]

Fu SH, Dong JX, Zhang MC, Xie XS. Alloy design and development of Inconel718 type alloy. Mater Sci Eng, A. 2009; 499(1-2): 215-220.
[12]

Liu L, Zhang J, Shen J, et al. Advances in directional solidification techniques of superalloys. Materials China. 2010; 29: 1-9.
[13]

Liu F, Sun WR, Yang SL, et al. Effect of Al on tensile properties of In718 alloys. Rare Metal Mater Eng. 2008; 6: 1046-1050.
[14]

Liu J, Li YM, Liu HJ. Effect of Al on microstructure and mechanical properties of as-cast K4169 alloy. Hot Work Technol. 2010; 11: 37-39.
[15]

Li XH, Zhang Y, Gu HP, et al. Study on heat-treated microstructure and mechanical properties of K4169 alloy. J Iron Steel Res. 2011; 2: 427-430.
[16]

Liu XZ, Wang XF. Effect of Al on solidification behavior of Ni-base superalloy. Hot Work Technol. 2016; 23: 107-108.
[17]

Gong L, Fu SH, Dong JX, et al. Investigation of strengthening effect of elements and structure stability of novel developed 718 alloys. Rare Met Mater Eng. 2007; 12: 2179-2183.
[18]

Xie XS, Dong JX, Chen W, et al. Investigation on modified nickel-base superalloys with combined precipitation of γ’’ and γ. Trans Mater Heat Treat. 1997; 18: 37.
[19]

Nedashkovskii KI, Zheleznyak ON, Gromyko BM, Kozykov BA, Mikhalev IA. Effect of low temperatures on mechanical and physical properties of high-strength nickel alloy ÉK61-ID and stainless maraging steel ÉK49-VD. Metal Sci heat Treat. 2003; 45(5/6): 233-236.
[20]

Cao WD, Kennedy RL. New developments in wrought 718-type superalloys. Acta Metall Sin. 2005; 18: 39.
[21]

Xu GH, Duan R, Wang L, Liu Y, Meng FQ. Effect of compositional homogenization on hot workability of Ni-based GH4061 superalloy. Trans Nonferrous Metals Soc China. 2023; 33(6): 1792-1802.
[22]

Zhang SZ, Li ZF, Wang R, et al. Effect of heat treatment on microstructure and properties of GH4061 alloy by selective laser melting. Aeronaut Manufact Technol. 2024; 67: 14-19.
[23]

Huang S, He YW, Xu GH, et al. Effect of vanadium on microstructure and mechanical properties of a wrought nickel-based superalloy. Chin J Mater Res. 2019; 33: 419-426.
[24]

Li ZM, Ludwig A, Savan A, Springer H, Raabe D. Combinatorial metallurgical synthesis and processing of high-entropy alloys. J Mater Res. 2018; 33(19): 3156-3169.
[25]

Zhao JC, Zheng X, Cahill DG. High-throughput diffusion multiples. Mater Today. 2005; 8(10): 28-37.
[26]

Zhao JC. Combinatorial approaches as effective tools in the study of phase diagrams and composition-structure-property relationships. Prog Mater Sci. 2006; 51(5): 557-631.
[27]

Wei CD, Zhao JC. Gradient temperature heat treatment for efficient study of phase precipitation in a high-temperature Fe-Cr-Mo ferritic steel. Materialia. 2018; 3: 31-40.
[28]

Zhao JC. The diffusion-multiple approach to designing alloys. Annu Rev Mater Sci. 2005; 35(1): 51-73.
[29]

Zhao JC. High-throughput experimental tools for the materials genome initiative. Chin Sci Bull. 2014; 59(15): 1652-1661.
[30]

Yao XY. Effect of Co and Al on Microstructure and Mechanical Properties of 718 Alloy. University of Science and Technology of China; 2022.
[31]

Zhang LK. Effect of Heat Treatment and Alloy Composition on Microstructure and Property of Ni-Base Superalloy K4169. Chongqing University; 2021.
[32]

Nathal MV, Maier RD, Ebert LJ. The influence of cobalt on the microstructure of the nickel-base superalloy MAR-M247. Metall Trans A. 1982; 13(10): 1775-1783.
[33]

Wang WZ, Jin T, Liu JL, Sun XF, Guan HR, Hu ZQ. Role of Re and Co on microstructures and γ′ coarsening in single crystal superalloys. Mater Sci Eng, A. 2008; 479(1-2): 148-156.
[34]

Cozar R, Pineau A. Influence of the Co/Ni Ratio on the γ and γ′′ precipitation in Fe-Ni-Co-Ta alloys. Metallurgical Mater Trans B. 1974; 5(11): 2471-2472,
[35]

Du JH, Lu XD, Deng Q, et al. Progress in GH4169 alloy development. Materials China. 2012; 31: 11-20.
[36]

Zhang C. Research on the Precipitation and Coarsening Behavior of γ′′ Phase in Alloy GH4169. Tianjin University; 2014.
[37]

Xie XS, Dong JX, Wang GL, et al. The effect of Nb, Ti, Al on precipitation and strengthening behavior of 718 type superalloys. The minerals. Metals or Materials Society. 2005: 287-298.
[38]

Xie XS, Dong JX, Fu SH, Zhang MC. Research and development of γ′′ and γ′ strengthened Ni-Fe base superalloy GH4169. Acta Metall Sin. 2010; 46(11): 1289-1302.
[39]

Mignanelli PM, Jones NG, Pickering EJ, et al. Gamma-gamma prime-gamma double prime dual-superlattice superalloys. Scr Mater. 2017; 136: 136-140.
[40]

Zhang LK, Wu XD, Zou Y, Wang JS, Cao LF. Effect of Nb content on microstructure and mechanical properties of K4169-type superalloy. J Mater Eng Perform. 2022; 31(5): 4204-4231.
[41]

Masoumi F, Jahazi M, Shahriari D, Cormier J. Coarsening and dissolution of γ′ precipitates during solution treatment of AD730™ Ni-based superalloy: mechanisms and kinetics models. J Alloys Compd. 2016; 658: 981-995.
[42]

Yao XY, Liu F, Yang SL, Liu D, Jia D, Sun WR. Effect of cobalt on the precipitation of Laves, γ′ and γ′′ phases in a 718 base alloy with 1.2 wt.% Al. J Mater Res Technol. 2021; 15: 4427-4436.
[43]

Wang K, Wang J, Kang MD, et al. Research status of the effects of alloying elements on microstructural stability of K4169 superalloy. Mater Rev. 2013; 27: 122-126.
[44]

Qiao Z. Effect of Al and Ti Contents on Microstructure in Inconel 718 Alloy. Tianjin University; 2019.
[45]

Collier JP, Wong SH, Tien JK, Phillips JC. The effect of varying Al, Ti, and Nb content on the phase stability of inconel 718. Metall Trans A. 1988; 19(7): 1657-1666.

RIGHTS & PERMISSIONS

2025 The Author(s). Materials Genome Engineering Advances published by Wiley-VCH GmbH on behalf of University of Science and Technology Beijing.

AI Summary AI Mindmap
PDF

44

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/