Low-Density, High-Temperature Co Base Superalloys

Literature Cited

1. 1. 

   Lee CS. 1971. Precipitation-hardening characteristics of ternary cobalt-aluminum-X alloys. PhD thesis Univ. Ariz. Tucson, AZ:
   [Google Scholar]
2. 2. 

   Sato J, Omori T, Oikawa K, Ohnuma I, Kainuma R, Ishida K. 2006. Cobalt-base high-temperature alloys. Science 312:577090–91
   [Google Scholar]
3. 3. 

   Mughrabi H. 2014. The importance of sign and magnitude of γ/γ′ lattice misfit in superalloys—with special reference to the new γ′-hardened cobalt-base superalloys. Acta Mater 81:21–29
   [Google Scholar]
4. 4. 

   Kobayashi S, Tsukamoto Y, Takasugi T, Chinen H, Omori T et al. 2009. Determination of phase equilibria in the Co-rich Co–Al–W ternary system with a diffusion-couple technique. Intermetallics 17:121085–89
   [Google Scholar]
5. 5. 

   Feng G, Li H, Li SS, Sha JB. 2012. Effect of Mo additions on microstructure and tensile behavior of a Co–Al–W–Ta–B alloy at room temperature. Scr. Mater. 67:5499–502
   [Google Scholar]
6. 6. 

   Chen M, Wang C-Y. 2009. First-principles investigation of the site preference and alloying effect of Mo, Ta and platinum group metals in γ′-Co₃(Al, W). Scr. Mater. 60:8659–62
   [Google Scholar]
7. 7. 

   Yan H-Y, Vorontsov VA, Dye D. 2014. Alloying effects in polycrystalline γ′ strengthened Co–Al–W base alloys. Intermetallics 48:44–53
   [Google Scholar]
8. 8. 

   Yan H-Y, Coakley J, Vorontsov VA, Jones NG, Stone HJ, Dye D. 2014. Alloying and the micromechanics of Co–Al–W–X quaternary alloys. Mater. Sci. Eng. A 613:201–8
   [Google Scholar]
9. 9. 

   Bauer A, Neumeier S, Pyczak F, Göken M. 2010. Microstructure and creep strength of different γ/γ′-strengthened Co-base superalloy variants. Scr. Mater. 63:121197–200
   [Google Scholar]
10. 10. 

    Knop M, Mulvey P, Ismail F, Radecka A, Rahman KM et al. 2014. A new polycrystalline Co-Ni superalloy. JOM 66:122495–501
    [Google Scholar]
11. 11. 

    Neumeier S, Freund LP, Göken M. 2015. Novel wrought γ/γ′ cobalt base superalloys with high strength and improved oxidation resistance. Scr. Mater. 109:104–7
    [Google Scholar]
12. 12. 

    Shi L, Yu JJ, Cui CY, Sun XF. 2015. Microstructural stability and tensile properties of a Ti-containing single-crystal Co–Ni–Al–W–base alloy. Mater. Sci. Eng. A 646:45–51
    [Google Scholar]
13. 13. 

    Bocchini PJ, Sudbrack CK, Noebe RD, Dunand DC, Seidman DN. 2017. Microstructural and creep properties of boron- and zirconium-containing cobalt-based superalloys. Mater. Sci. Eng. A 682:260–69
    [Google Scholar]
14. 14. 

    Makineni SK, Nithin B, Chattopadhyay K. 2015. A new tungsten-free γ–γ′ Co–Al–Mo–Nb-based superalloy. Scr. Mater. 98:36–39
    [Google Scholar]
15. 15. 

    Makineni SK, Samanta A, Rojhirunsakool T, Alam T, Nithin B et al. 2015. A new class of high strength high temperature Cobalt based γ–γ′ Co–Mo–Al alloys stabilized with Ta addition. Acta Mater 97:29–40
    [Google Scholar]
16. 16. 

    Makineni SK, Nithin B, Chattopadhyay K. 2015. Synthesis of a new tungsten-free γ–γ′ cobalt-based superalloy by tuning alloying additions. Acta Mater 85:85–94
    [Google Scholar]
17. 17. 

    Makineni SK, Nithin B, Palanisamy D, Chattopadhyay K. 2016. Phase evolution and crystallography of precipitates during decomposition of new “tungsten-free” Co(Ni)–Mo–Al–Nb γ–γ′ superalloys at elevated temperatures. J. Mater. Sci. 51:177843–60
    [Google Scholar]
18. 18. 

    Pandey P, Mukhopadhyay S, Srivastava C, Makineni SK, Chattopadhyay K. 2020. Development of new γ′-strengthened Co-based superalloys with low mass density, high solvus temperature and high temperature strength. Mater. Sci. Eng. A 790:139578
    [Google Scholar]
19. 19. 

    Singh MP, Makineni SK, Chattopadhyay K. 2020. Achieving lower mass density with high strength in Nb stabilised γ/γ′ Co–Al–Mo–Nb base superalloy by the replacement of Mo with V. Mater. Sci. Eng. A 794:139826
    [Google Scholar]
20. 20. 

    Yao Q, Shang S-L, Hu Y-J, Wang Y, Wang Y et al. 2016. First-principles investigation of phase stability, elastic and thermodynamic properties in L1₂ Co₃(Al,Mo,Nb) phase. Intermetallics 78:1–7
    [Google Scholar]
21. 21. 

    Tanaka K, Ohashi T, Kishida K, Inui H. 2007. Single-crystal elastic constants of Co₃ (Al, W) with the L1₂ structure. Appl. Phys. Lett. 91:18181907
    [Google Scholar]
22. 22. 

    Omori T, Oikawa K, Sato J, Ohnuma I, Kattner UR et al. 2013. Partition behavior of alloying elements and phase transformation temperatures in Co–Al–W–base quaternary systems. Intermetallics 32:274–83
    [Google Scholar]
23. 23. 

    Chen Y, Wang C, Ruan J, Omori T, Kainuma R et al. 2019. High-strength Co–Al–V-base superalloys strengthened by γ′-Co₃(Al,V) with high solvus temperature. Acta Mater 170:62–74
    [Google Scholar]
24. 24. 

    Chen Y, Wang C, Ruan J, Yang S, Omori T et al. 2020. Development of low-density γ/γ′ Co–Al–Ta-based superalloys with high solvus temperature. Acta Mater 188:652–64
    [Google Scholar]
25. 25. 

    Murray JL. 1982. The Co−Ti (cobalt−titanium) system. Bull. Alloy Phase Diagr. 3:174
    [Google Scholar]
26. 26. 

    Bhowmik A, Neumeier S, Rhode S, Stone HJ. 2015. Allotropic transformation induced stacking faults and discontinuous coarsening in a γ-γ′ Co-base alloy. Intermetallics 59:95–101
    [Google Scholar]
27. 27. 

    Blaise JM, Viatour P, Drapier JM 1970. On the stability and precipitation of the Co₃Ti phase in Co-Ti alloys. Cobalt 49:192–95
    [Google Scholar]
28. 28. 

    Viatour P, Drapier JM, Coutsouradis D 1973. Stability of the gamma prime-Co₃Ti compound in simple and complex cobalt alloys. Cobalt 3:67–74
    [Google Scholar]
29. 29. 

    Zenk CH, Povstugar I, Li R, Rinaldi F, Neumeier S et al. 2017. A novel type of Co–Ti–Cr-base γ/γ′ superalloys with low mass density. Acta Mater 135:244–51
    [Google Scholar]
30. 30. 

    Im HJ, Makineni SK, Gault B, Stein F, Raabe D, Choi P-P. 2018. Elemental partitioning and site-occupancy in γ/γ′ forming Co-Ti-Mo and Co-Ti-Cr alloys. Scr. Mater. 154:159–62
    [Google Scholar]
31. 31. 

    Im HJ, Lee S, Choi WS, Makineni SK, Raabe D et al. 2020. Effects of Mo on the mechanical behavior of γ/γ′-strengthened Co-Ti-based alloys. Acta Mater 197:69–80
    [Google Scholar]
32. 32. 

    Ruan JJ, Wang CP, Zhao CC, Yang SY, Yang T, Liu XJ 2014. Experimental investigation of phase equilibria and microstructure in the Co-Ti-V ternary system. Intermetallics 49:121–31
    [Google Scholar]
33. 33. 

    Yoo B, Im HJ, Seol J-B, Choi P-P. 2019. On the microstructural evolution and partitioning behavior of L1₂-structured γ′-based Co-Ti-W alloys upon Cr and Al alloying. Intermetallics 104:97–102
    [Google Scholar]
34. 34. 

    Nyshadham C, Oses C, Hansen JE, Takeuchi I, Curtarolo S, Hart GL. 2017. A computational high-throughput search for new ternary superalloys. Acta Mater 122:438–47
    [Google Scholar]
35. 35. 

    Reyes Tirado FL, Perrin Toinin J, Dunand DC 2018. γ+γ′ microstructures in the Co-Ta-V and Co-Nb-V ternary systems. Acta Mater 151:137–48
    [Google Scholar]
36. 36. 

    Ruan J, Xu W, Yang T, Yu J, Yang S et al. 2020. Accelerated design of novel W-free high-strength Co-base superalloys with extremely wide γ/γ′ region by machine learning and CALPHAD methods. Acta Mater 186:425–33
    [Google Scholar]
37. 37. 

    Mukhopadhyay S, Pandey P, Baler N, Biswas K, Makineni SK, Chattopadhyay K. 2021. The role of Ti addition on the evolution and stability of γ/γ′ microstructure in a Co-30Ni-10Al-5Mo-2Ta alloy. Acta Mater 208:116736
    [Google Scholar]
38. 38. 

    Pandey P, Sawant AK, Nithin B, Peng Z, Makineni SK et al. 2019. On the effect of Re addition on microstructural evolution of a CoNi-based superalloy. Acta Mater 168:37–51
    [Google Scholar]
39. 39. 

    Nithin B, Samanta A, Makineni SK, Alam T, Pandey P et al. 2017. Effect of Cr addition on γ–γ′ cobalt-based Co–Mo–Al–Ta class of superalloys: a combined experimental and computational study. J. Mater. Sci. 52:1811036–47
    [Google Scholar]
40. 40. 

    Pandey P, Makineni SK, Samanta A, Sharma A, Das SM et al. 2019. Elemental site occupancy in the L1₂ A₃B ordered intermetallic phase in Co-based superalloys and its influence on the microstructure. Acta Mater 163:140–53
    [Google Scholar]
41. 41. 

    Baler N, Pandey P, Singh MP, Makineni SK, Chattopadhyay K Effects of Ti and Cr additions in a Co-Ni-Al-Mo-Nb based superalloy. In Superalloys 2020 S Tin, M Hardy, J Clews, J Cormier, Q Feng et al.929–36 Cham, Switz.: Springer
    [Google Scholar]
42. 42. 

    Li L, Wang C, Chen Y, Yang S, Yang M et al. 2019. Effect of Re on microstructure and mechanical properties of γ/γ′ Co-Ti-based superalloys. Intermetallics 115:106612
    [Google Scholar]
43. 43. 

    Povstugar I, Zenk CH, Li R, Choi P-P, Neumeier S et al. 2016. Elemental partitioning, lattice misfit and creep behaviour of Cr containing γ′ strengthened Co base superalloys. Mater. Sci. Technol. 32:3220–25
    [Google Scholar]
44. 44. 

    Povstugar I, Choi P-P, Neumeier S, Bauer A, Zenk CH et al. 2014. Elemental partitioning and mechanical properties of Ti- and Ta-containing Co–Al–W-base superalloys studied by atom probe tomography and nanoindentation. Acta Mater 78:78–85
    [Google Scholar]
45. 45. 

    Shinagawa K, Omori T, Sato J, Oikawa K, Ohnuma I et al. 2008. Phase equilibria and microstructure on γ′ phase in Co-Ni-Al-W system. Mater. Trans. 49:61474–79
    [Google Scholar]
46. 46. 

    Volz N, Zenk CH, Cherukuri R, Kalfhaus T, Weiser M et al. 2018. Thermophysical and mechanical properties of advanced single crystalline Co-base superalloys. Metall. Mater. Trans. A 49:94099–109
    [Google Scholar]
47. 47. 

    Kolb M, Zenk CH, Kirzinger A, Povstugar I, Raabe D et al. 2017. Influence of rhenium on γ′-strengthened cobalt-base superalloys. J. Mater. Res. 32:132551–59
    [Google Scholar]
48. 48. 

    Liu Q, Coakley J, Seidman DN, Dunand DC. 2016. Precipitate evolution and creep behavior of a W-free Co-based superalloy. Metall. Mater. Trans. A 47:126090–96
    [Google Scholar]
49. 49. 

    Ruan JJ, Liu XJ, Yang SY, Xu WW, Omori T et al. 2018. Novel Co-Ti-V-base superalloys reinforced by L1₂-ordered γ′ phase. Intermetallics 92:126–32
    [Google Scholar]
50. 50. 

    Zhuang X, Lu S, Li L, Feng Q. 2020. Microstructures and properties of a novel γ′-strengthened multi-component CoNi-based wrought superalloy designed by CALPHAD method. Mater. Sci. Eng. A 780:139219
    [Google Scholar]
51. 51. 

    Suzuki A, Inui H, Pollock TM. 2015. L1₂-strengthened cobalt-base superalloys. Annu. Rev. Mater. Res. 45:345–68
    [Google Scholar]
52. 52. 

    Calderon HA, Voorhees PW, Murray JL, Kostorz G. 1994. Ostwald ripening in concentrated alloys. Acta Metall. Mater. 42:3991–1000
    [Google Scholar]
53. 53. 

    Sauza DJ, Bocchini PJ, Dunand DC, Seidman DN. 2016. Influence of ruthenium on microstructural evolution in a model Co–Al–W superalloy. Acta Mater 117:135–45
    [Google Scholar]
54. 54. 

    Azzam A, Philippe T, Hauet A, Danoix F, Locq D et al. 2018. Kinetics pathway of precipitation in model Co-Al-W superalloy. Acta Mater 145:377–87
    [Google Scholar]
55. 55. 

    Meher S, Nag S, Tiley J, Goel A, Banerjee R. 2013. Coarsening kinetics of γ′ precipitates in cobalt-base alloys. Acta Mater 61:114266–76
    [Google Scholar]
56. 56. 

    Baler N, Pandey P, Palanisamy D, Makineni SK, Phanikumar G, Chattopadhyay K. 2020. On the effect of W addition on microstructural evolution and γ′ precipitate coarsening in a Co–30Ni–10Al–5Mo–2Ta–2Ti alloy. Materialia 10:100632
    [Google Scholar]
57. 57. 

    Lass EA, Grist RD, Williams ME. 2016. Phase equilibria and microstructural evolution in ternary Co-Al-W between 750 and 1100°C. J. Phase Equilib. Diffus. 37:4387–401
    [Google Scholar]
58. 58. 

    Hadjiapostolidou D, Shollock BA. 2008. Long term coarsening in René 80 Ni-base superalloy. Superalloys 2008 733–739
    [Google Scholar]
59. 59. 

    Footner PK, Richards BP. 1982. Long—term growth of superalloy γ′ particles. J. Mater. Sci. 17:72141–53
    [Google Scholar]
60. 60. 

    MacKay RA, Nathal MV. 1990. γ′ coarsening in high volume fraction nickel-base alloys. Acta Metall. Mater. 38:6993–1005
    [Google Scholar]
61. 61. 

    MacKay RA, Ebert LJ. 1983. The development of directional coarsening of the γ′ precipitate in superalloy single crystals. Scr. Metall. 17:101217–22
    [Google Scholar]
62. 62. 

    Miyazaki T, Imamura H, Kozakai T. 1982. The formation of “γ′ precipitate doublets” in Ni·Al alloys and their energetic stability. Mater. Sci. Eng. 54:19–15
    [Google Scholar]
63. 63. 

    Qu S, Li Y, Wang C, Liu X, Qian K et al. 2020. Coarsening behavior of γ′ precipitates and compression deformation mechanism of a novel Co–V–Ta–Ti superalloy. Mater. Sci. Eng. A 787:139455
    [Google Scholar]
64. 64. 

    Takasugi T, Hirakawa S, Izumi O, Ono S, Watanabe S. 1987. Plastic flow of Co₃ Ti single crystals. Acta Metall 35:82015–26
    [Google Scholar]
65. 65. 

    Liu Y, Takasugi T, Izumi O, Suenaga H. 1989. Mechanical properties of Co₃Ti polycrystals alloyed with various additions. J. Mater. Sci. 24:124458–66
    [Google Scholar]
66. 66. 

    Suzuki A, DeNolf GC, Pollock TM. 2007. Flow stress anomalies in γ/γ′ two-phase Co–Al–W-base alloys. Scr. Mater. 56:5385–88
    [Google Scholar]
67. 67. 

    Suzuki A, Pollock TM. 2008. High-temperature strength and deformation of γ/γ′ two-phase Co–Al–W-base alloys. Acta Mater 56:61288–97
    [Google Scholar]
68. 68. 

    Mishima Y, Ochiai S, Yodogawa M, Suzuki T. 1986. Mechanical properties of Ni₃Al with ternary addition of transition metal elements. Trans. Jpn. Inst. Metals 27:141–50
    [Google Scholar]
69. 69. 

    Okamoto NL, Oohashi T, Adachi H, Kishida K, Inui H, Veyssière P. 2011. Plastic deformation of polycrystals of Co₃(Al,W) with the L1₂ structure. Philos. Mag. 91:283667–84
    [Google Scholar]
70. 70. 

    Vamsi KV, Karthikeyan S. 2017. Yield anomaly in L1₂ Co₃Al_xW_1–x vis-à-vis Ni₃Al. Scr. Mater. 130:269–73
    [Google Scholar]
71. 71. 

    Long FR, Baik SI, Chung DW, Xue F, Lass EA et al. 2020. Microstructure and creep performance of a multicomponent Co-based L1₂-ordered intermetallic alloy. Acta Mater 196:396–408
    [Google Scholar]
72. 72. 

    Vitek V, Paidar V. 2008. Non-planar dislocation cores: a ubiquitous phenomenon affecting mechanical properties of crystalline materials. Dislocations Solids 14:439–514
    [Google Scholar]
73. 73. 

    Kear BH, Wilsdorf HG. 1962. Dislocation configurations in plastically deformed polycrystalline Cu₃Au alloys. Trans. Met. Soc. AIME 224:382
    [Google Scholar]
74. 74. 

    Sharma A. 2019. An evaluation of the mechanical behavior of some new high temperature materials. PhD Thesis Indian Inst. Sci. Bangalore, India:
    [Google Scholar]
75. 75. 

    Bauer A, Neumeier S, Pyczak F, Göken M. 2012. Creep strength and microstructure of polycrystalline γ′-strengthened cobalt-base superalloys. Superalloys 12:695–703
    [Google Scholar]
76. 76. 

    Reyes Tirado FL, Taylor S, Dunand DC 2019. Effect of Al, Ti and Cr additions on the γ-γ′ microstructure of W-free Co-Ta-V-based superalloys. Acta Mater 172:44–54
    [Google Scholar]
77. 77. 

    Bauer A, Neumeier S, Pyczak F, Singer RF, Göken M. 2012. Creep properties of different γ′-strengthened Co-base superalloys. Mater. Sci. Eng. A 550:333–41
    [Google Scholar]
78. 78. 

    Reyes Tirado FL, Taylor SV, Dunand DC 2020. Low-density, W-free Co–Nb–V–Al-based superalloys with γ/γ′ microstructure. Mater. Sci. Eng. A 796:139977
    [Google Scholar]
79. 79. 

    Ng DS, Chung D-W, Toinin JP, Seidman DN, Dunand DC, Lass EA. 2020. Effect of Cr additions on a γ-γ′ microstructure and creep behavior of a Co-based superalloy with low W content. Mater. Sci. Eng. A 778:139108
    [Google Scholar]
80. 80. 

    Klein L, Bauer A, Neumeier S, Göken M, Virtanen S. 2011. High temperature oxidation of γ/γ′-strengthened Co-base superalloys. Corros. Sci. 53:52027–34
    [Google Scholar]
81. 81. 

    Klein L, Killian MS, Virtanen S. 2013. The effect of nickel and silicon addition on some oxidation properties of novel Co-based high temperature alloys. Corros. Sci. 69:43–49
    [Google Scholar]
82. 82. 

    Klein L, Shen Y, Killian MS, Virtanen S. 2011. Effect of B and Cr on the high temperature oxidation behaviour of novel γ/γ′-strengthened Co-base superalloys. Corros. Sci. 53:92713–20
    [Google Scholar]
83. 83. 

    Weiser M, Galetz MC, Zschau H-E, Zenk CH, Neumeier S et al. 2019. Influence of Co to Ni ratio in γ′-strengthened model alloys on oxidation resistance and the efficacy of the halogen effect at 900°C. Corros. Sci. 156:84–95
    [Google Scholar]
84. 84. 

    Weiser M, Eggeler YM, Spiecker E, Virtanen S. 2018. Early stages of scale formation during oxidation of γ/γ′ strengthened single crystal ternary Co-base superalloy at 900°. Corros. Sci. 135:78–86
    [Google Scholar]
85. 85. 

    Stewart CA, Suzuki A, Rhein RK, Pollock TM, Levi CG. 2019. Oxidation behavior across composition space relevant to Co-based γ/γ′ alloys. Metall. Mater. Trans. A 50:115445–58
    [Google Scholar]
86. 86. 

    Stewart CA, Murray SP, Suzuki A, Pollock TM, Levi CG. 2020. Accelerated discovery of oxidation resistant CoNi-base γ/γ′ alloys with high L1₂ solvus and low density. Mater. Des. 189:108445
    [Google Scholar]
87. 87. 

    Forsik SAJ, Polar Rosas AO, Wang T, Colombo GA, Zhou N et al. 2018. High-temperature oxidation behavior of a novel Co-base superalloy. Metall. Mater. Trans. A 49:94058–69
    [Google Scholar]
88. 88. 

    Weiser M, Virtanen S. 2019. Influence of W content on the oxidation behaviour of ternary γ′-strengthened Co-based model alloys between 800 and 900°C. Oxid. Met. 92:5541–60
    [Google Scholar]
89. 89. 

    Moskal G, Tomaszewska A, Mikuszewski T, Maciag T, Godzierz M, Niemiec D. 2017. Oxidation performance of Co–Al–W and Co–Ni–Al–W new type γ–γ′ cobalt-based superalloys. Mater. Eng. 4:163–69
    [Google Scholar]
90. 90. 

    Migas D, Moskal G, Niemiec D. 2018. Surface condition of new γ–γ′ Co-Al-Mo-Nb and Co-Al-W cobalt-based superalloys after oxidation at 800°C. J. Mater. Eng. Perform. 27:2447–56
    [Google Scholar]
91. 91. 

    Moskal G, Migas D, Niemiec D, Tomaszewska A. 2019. Thermogravimetric investigations of novel γ–γ′ Co-Al-W and Co-Al-Mo-Nb cobalt-based superalloys. J. Eng. Mater. Technol. 141:4041008
    [Google Scholar]
92. 92. 

    Das SM, Singh MP, Chattopadhyay K. 2019. Evolution of oxides and their microstructures at 800°C in a γ-γ’ stabilised Co-Ni-Al-Mo-Ta superalloy. Corros. Sci. 155:46–54
    [Google Scholar]
93. 93. 

    Das SM, Singh MP, Chattopadhyay K. 2020. Effect of Cr addition on the evolution of protective alumina scales and the oxidation properties of a Ta stabilized γ′-strengthened Co-Ni-Al-Mo-Ta-Ti alloy. Corros. Sci. 172:108683
    [Google Scholar]
94. 94. 

    Chen Y, Xue F, Wang C, Li X, Deng Q et al. 2019. Effect of Cr on the microstructure and oxidation properties of Co-Al-W superalloys studied by in situ environmental TEM. Corros. Sci. 161:108179
    [Google Scholar]
95. 95. 

    Bantounas I, Gwalani B, Alam T, Banerjee R, Dye D. 2019. Elemental partitioning, mechanical and oxidation behaviour of two high-γ′ W-free γ/γ′ polycrystalline Co/Ni superalloys. Scr. Mater. 163:44–50
    [Google Scholar]
96. 96. 

    Nithin B, Chattopadhyay K, Phanikumar G. 2018. Characterization of the hot deformation behavior and microstructure evolution of a new γ-γ′ strengthened cobalt-based superalloy. Metall. Mater. Trans. A 49:104895–905
    [Google Scholar]
97. 97. 

    Baler N, Pandey P, Chattopadhyay K, Phanikumar G. 2020. Influence of thermomechanical processing parameters on microstructural evolution of a gamma-prime strengthened cobalt based superalloy during high temperature deformation. Mater. Sci. Eng. A 791:13949
    [Google Scholar]