Hostname: page-component-5c6d5d7d68-qks25 Total loading time: 0 Render date: 2024-08-22T08:59:35.140Z Has data issue: false hasContentIssue false
  • English
  • Français

Ordered Alloys for High Temperature Applications

Published online by Cambridge University Press:  21 February 2011

Norman S. Stoloff
Norman S. Stoloff*
Affiliation:
Materials Engineering Department, Rensselaer Polytechnic Institute, Troy, NY 12181
Get access

Abstract

This paper will provide an overview of the current status of the development of ordered alloys for high temperature structural applications. The physical and mechanical properties of ordered alloys will be reviewed with particular emphasis on aluminides and (FeNiCo)3V alloys. Alloy theory, slip systems, yielding, strain hardening, fatigue, wear resistance and processing are among the subjects to be covered. Current research programs in the U.S. and abroad will be outlined, and the kinds of scientific and application-oriented research needed in the future will be discussed.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 39: Symposium G – High-Temperature Ordered Intermetallic Alloys I , 1984 , 3
Copyright
Copyright © Materials Research Society 1985

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1. Warlimont, H., Ed., Order Disorder Transformations in Alloys, (Springer-Verlag, Berlin, 1974.Google Scholar
2. Kear, B.H., et al, Eds., Ordered Alloys - Physical Metallurgy and Structural Applications, Claitor's Publ. Div., Baton Rouge, LA, 1970.Google Scholar
3. Lipsitt, H., Aviation Week, 81, Jan. 26, 1976.Google Scholar
4. Liu, C.T., Met. Trans., 4, 1743 (1973).CrossRefGoogle Scholar
5. Liu, C.T., J. Nucl. Mat. 85–86, 907 (1979).Google Scholar
6. Aoki, K. and Izumi, O.,Nippon Kinzoku Gakkaishi, 43, 1190 (1979).Google Scholar
7. Liu, C.T., White, C.L., Koch, C.C. and Lee, E.H., Preparation of Ductile Nickel Aluminides for High Temperature Use, in Proceedings of the Conference on High Temperature Materials Chemistry, Princeton, New Jersey: Electrochemical Society, in press (1984).Google Scholar
8. Taub, A.I., Huang, S.C., Met. Trans. A, 15A, 399 (1984).Google Scholar
9. Stoloff, N.S., Int. Met. Rev. 29, 123 (1984).Google Scholar
10. Liu, C.T., Int. Met. Rev. 29, 169, (1984).Google Scholar
11. Pope, D.P. and Ezz, S.S., Int. Met. Rev. 29, 136 (1984).Google Scholar
12. Schulson, E.M., Int. Met. Rev. 29, 195 (1984).CrossRefGoogle Scholar
13. Brooks, C.R., Spruiell, J.E. and Stansbury, E.E., Int. Met. Rev., 29, 210 (1984).Google Scholar
14. “Structural Uses for Ductile Ordered Alloys”, NMAB-419, National Academy Press, Washington, D.C. (1984).Google Scholar
15. Lawley, A. in Intermetallic Compounds, Ed. by Westbrook, J.H., New York: (John Wiley and Sons, New York, 1967), pp. 464490.Google Scholar
16. Stoloff, N.S. and Davies, R.G., The Mechanical Properties of Ordered Alloys, Prog. in Mat. Sci., 13, 1 (1966).Google Scholar
17. Stoloff, N.S., in Strengthening Methods in Crystals, Ed. Kelly, A. and Nicholson, R.B., (Elsevier, New York, 1971) pp. 193259.Google Scholar
18. Marcinkowski, M.J., in Treatise on Materials Science and Technology, Ed. Herman, H., (Academic Press, New York, 1974) pp. 333-Google Scholar
19. Nesbit, L.A. and Laughlin, D.E., Acta Met., 29, 989 (1980).Google Scholar
20. Morgand, P., Mouturat, P. and Sainfort, G., Acta Met. 16, 867 (1968).Google Scholar
21. Calvayrac, Y. and Fayard, M., Phys. Stat. Sol. 17, 407 (1973).Google Scholar
22. Ardley, G.W., Acta Met. 3, 525 (1955).CrossRefGoogle Scholar
23. Flinn, P.A., Trans. TMS-AIME, 218, 145 (1960).Google Scholar
24. Yodogawa, M., Wee, D.M., Oya, Y. and Suzuki, T., Scripta Met, 14, 849 (1980).Google Scholar
25. Inoue, A., Tomioku, H. and Nasumoto, T., Net. Trans. A, 14A, 1367 (1983).Google Scholar
26. Liu, C.T., Oak Ridge National Lab, unpublishedGoogle Scholar
27. Mendiratta, M.G., Kim, H.M. and Lipsitt, H.A., Met. Trans. A, 15A, 394 (1984).Google Scholar
28. Thornton, P.H., Davies, R.G. and Johnston, T.L., Met. Trans., 1, 207 (1970).Google Scholar
29. Mikkola, D.E., Cohen, J.B., Acta Net, 14, 105 (1966).Google Scholar
30. Davies, R.G. and Stoloff, N.S., Phil. Mag., 12, 297 (1965).CrossRefGoogle Scholar
31. Noguchi, O., Oya, Y. and Suzuki, T., Met. Trans. A, 12A, 1647 (1981).Google Scholar
32. Guard, R.W. and Westbrook, J.H., Trans. Net. Soc. AIME, 215, 807 (1959).Google Scholar
33. Aoki, K. and Izumi, O., Phys. Stat. Sol. (a) 32, 657 (1975).Google Scholar
34. Wolfenden, A. and Marmouche, N., J. Metals 35 (12), 90 (1983).Google Scholar
35. Schrafik, R.E., Met. Trans. A 8A, 1003 (1977).Google Scholar
36. Ray, R., Panchanathan, V. and Isserow, S., J. Metals 35(6), 30 (1983).Google Scholar
37. Kuramoto, E. and Pope, D.P., Acta Net. 26, 207 (1978).Google Scholar
38. Davies, R.G. and Johnson, T.L. in Ordered Alloys-Structural Application and Physical Metallurgy, Kear, B.H., et al, Eds., Claitor's Publ. Div., Baton Rouge, LA, pp. 447- (1970).Google Scholar
39. Umakoski, Y., Boland, J.R., Pope, D.P. and Vitek, V., Nat. Sci. Eng., 64, 27, (1984).Google Scholar
40. Ezz, S.S., Pope, D.P. and Paidar, V., Acta Net., 30, 921, (1984).Google Scholar
41. Suzuki, T., Oya, Y. and Wee, D.M., Acta Net., 28, 301 (1980).Google Scholar
42. Kear, B.H. and Wilsdorf, H.G.F., Trans. TMS-AIME 224, 382 (1962).Google Scholar
43. Stoloff, N.S. and Davies, R.G., Acta Met, 12, 473, (1964).Google Scholar
44. Inoue, H., Oak Ridge National Lab, this meeting.Google Scholar
45. Fujita, A., Mishima, Y. and Suzuki, T., J. Mat. Sci., 18, 1881 (1983).Google Scholar
46. Hanada, S., Watanabe, S., Sato, T. and Izumi, I., Scripta Met, 15, 1345, (1981).Google Scholar
47. Wegen, G.J.L. Van der, Bronsveld, P.M. and Hosson, J. Th. N. De, Acta Met., 30, 1537 (1982).Google Scholar
48. Vidoz, A.E. and Brown, L.N., Phil. Nag. 7, 1167 (1962).Google Scholar
49. Ehlers, S.K. and Mendiratta, M.G., J. Metals, 34(12). 80 (1982).Google Scholar
50. Kawahara, K., J. Mat. Sci. 18, 1709 (1983).Google Scholar
51. Stoloff, N.S. and Dillamore, I.L. in Ordered Alloys, Structural Application and Physical Metallurgy, by Kear, B.H., et al, Eds., Claitor's Publ. Div., pp. 525544 Baton Rouge, LA (1970).Google Scholar
52. Shea, M.M. and Stoloff, N.S., Met. Trans. 5, 755 (1974).Google Scholar
53. Marcinkowski, M.J., Taylor, M.E. and Kayser, F.X., J. Mat. Sci., 10, 406 (1975).Google Scholar
54. Fuchs, G. and Stoloff, N.S., Rensselaer Polytechnic Inst., unpublished (1984).Google Scholar
55. Blackburn, M.J., Trans. TMS-AIME, 239, 600 (1967).Google Scholar
56. Schafrik, R., Lipsitt, H.A. and Schectman, D., AFWAL, Wright Patterson AFB, Ohio, unpublished.Google Scholar
57. Lipsitt, H.A., Shechtman, D. and Schafrik, R.E., Met. Trans. A 6A, 1991 (1975).Google Scholar
58. Chaterjee, D.K. and Mendiratta, M.G., J. Metals 33(12), 5 (1981).Google Scholar
59. Ehlers, S.K. and Mendiratta, M.G., J. Metals 33(12), 5 (1981).Google Scholar
60. Stoloff, N.S. and Davies, R.G., Trans. ASM 57, 247 (1964).Google Scholar
61. Westbrook, J.H. and Wood, D.L., J. Inst. Met. 91, 174 (1963).Google Scholar
62. Liu, C.T., et al, ORNL 6067, Oak Ridge National Laboratory (1983).Google Scholar
63. Liu, C.T. and Koch, C.C., Development of Ductile Polycrystalline Ni3 Al for High Temperature Applications in Proceedings of the Conference on Trends in Critical Materials Requirements for Steels of the Future, Vanderbilt Univ., Nashville, TN (1982).Google Scholar
64. Taub, A.I., Huang, S.C. and Chang, K.M., unpublished.Google Scholar
65. Vedula, K., abstract TMS-AIME Fall Meeting, Detroit, MI, J. of Met., (1984).Google Scholar
66. Koch, C.C., North Carolina State Univ., unpublished (1984).Google Scholar
67. Liu, C.T. and Inoue, H., Met. Trans. A 10A, 1515 (1979).Google Scholar
68. Beck, P.A., Adv. X-ray Anal. 12, 1 (1969).Google Scholar
69. Schulson, E.M., and Barker, D.R., Scripta Met., 17, 519 (1983).Google Scholar
70. Schulson, E.M., Res. Mecanica Letters 1, 111, (1983).Google Scholar
71. Schulson, E.M., COSAM Program Overview, p. 175. NASA TN 830006, National Aeronautics and Space Administration, Washington, D.C. (1982).Google Scholar
72. Inoue, A., Tomioku, H. and Masumoto, T., Met. Trans A 14A, 1367 (1983).Google Scholar
73. Koch, C.C., Horton, J.A., Liu, C.T., Cavin, O.B. and Scarbrough, J.O, in Rapid Solidification Processing Principles and Technologies III, Mehrabian, R., Ed., National Bureau of Standards (1983) pp. 264269.Google Scholar
74. “Structural Uses for Ductile Ordered Alloys”, NMAB-419, National Academy Press, Washington, D.C., p. 74 (1984).Google Scholar
75. Chaterjee, D.K. and Mendiratta, M.G., J. Met 33(12), 6 (1981).Google Scholar
76. Slaughter, E.R. and Das, S.K. in Proc. of Second International Conference on Rapid Solidification Processing, Claitor's Publ. Div., Baton Rouge, LA, pp. 354–363 (1980).Google Scholar
77. Baker, I., Ishishita, F. and Schulson, E.M., Proc. MRS Symp. on Rapid Solidification Processing, Nov. 14–17, Boston, MA, in press (1983).Google Scholar
78. Kuruvilla, A.K. and Stoloff, N.S., Met. Trans. A, in press (1984).Google Scholar
79. Lawley, A., Coli, J.A. and Cahn, R.W., Trans. Net. Soc. AIME 218, 166 (1960).Google Scholar
80. Vandervoort, R.R., Nukherjee, A.K. and Dorm, J.E., Trans. ASM 59, 930 (1966).Google Scholar
81. Strutt, P.R. and Dodd, R.A., in Ordered Alloys: Structural Applications and Physical Metallurgy, Kear, B.H., et al, Eds., Claitor's Publ. Div., Baton Rouge, LA, pp. 475503 (1969).Google Scholar
82. Leverant, G. and Duhl, D., quoted in ref. 81.Google Scholar
83. Johnston, T.L., Davies, R.G. and Stoloff, N.S., Phil. Nag. 12, 305 (1965).Google Scholar
84. Chien, K.H. and Starke, E.A., Acta Met., 23, 1173 (1975).Google Scholar
85. Whittenberger, J.D., Nat. Sci. and Eng. 57, 77 (1983).Google Scholar
86. Boettner, R.C., Stoloff, N.S. and Davies, R.G., Trans. TMS-AIME, 236, 131 (1966).Google Scholar
87. Williams, H.D. and Smith, G.C., Phil. Nag. 13, 835 (1966).Google Scholar
88. McClintock, F. quoted in Tschegg, E. and Stanzl, S., Acta Met. 33, 33 (1981).Google Scholar
89. Sastry, S.M.L. and Lipsitt, H.A., Net. Trans. A, 8A, 299 (1977).Google Scholar
90. Sastry, S.M.L. and Lipsitt, H.A., Acta Met. 25, 1279 (1977).Google Scholar
91. Ashok, S., Kain, K., Tartaglia, J. and Stoloff, N.S., Met. Trans. A, 14A, 1997 (1983).Google Scholar
92. Gittins, A., Met. Sci. J. 2, 114 (1968).Google Scholar
93. Pak, H.-r., New Mexico State Univ., unpublished.Google Scholar
94. Stoloff, N.S., unpublished proposal to National Science Foundation, (1983).Google Scholar
95. Barnatt, S., Corrosion 18, 322 (1962).Google Scholar
96. Saxena, M.N. and Dodd, R.A., in Environment-Sensitive Mechanical Behavior, Ed. Westwood, A.R.C. and Stoloff, N.S., (Gordon and Breach, New York 1966), pp. 455479.Google Scholar
97. Berkowitz, B.J. and Miller, C., Net. Trans. A, 11A, 1877 (1980).Google Scholar
98. Asphahani, A.I., in Proceedings of the Second International Congress on Hydrogen in Metals, No. 4, Sec. C, Paper 2, (Pergamon Press, New York, 1977).Google Scholar
99. Kuruvilla, A.K., Ashok, S. and Stoloff, N.S., in Proceedings of the Third International Congress on Hydrogen in Metals, No. 4 (Pergamon Press, New York, 1980) pp. 629633.Google Scholar
100. Kuruvilla, A.K. and Stoloff, N.S., Scripta Met, in press (1984).Google Scholar
101. Ogino, Y. and Yamasaki, T., Scripta Met, 15, 821 (1981).Google Scholar
102. Messmer, R.P. and Briant, C.L., Acta Met, 30, 457 (1982).CrossRefGoogle Scholar
103. Wakefield, S.., Beck, F.H. and Powell, G.W., Corrosion, 40, 190 (1984).Google Scholar
104. Fontana, M.G. and Greene, N.D., Corrosion Engineering (McGraw Hill Book Co., New York, 1967) p. 161.Google Scholar
105. Mughrabi, H. in ASTM STP 675 (complete reference to be supplied).Google Scholar
106. Griess, J.C., Liu, C.T. and Devan, J.H., Oak Ridge National Lab, unpublished (1984) (See also ref. 10).Google Scholar
107. Bailey, J.A. and Sikorski, M.E., Wear, 14, 181 (1969).Google Scholar
108. Buckley, D.H., Influence of Order-Disorder Transformation on Friction Characteristics of Copper-Gold Alloys in Vacuum, NASA TN D-2985, Washington, D.C., NASA, Washington, D.C. (1965).Google Scholar
Wright, R.N. and Mikkola, D.E., Mat. Sci. Eng. 26, 263 (1976).Google Scholar
110. Wee, D.M., Noguchi, O., Oya, Y. and Suzuki, T., Trans. Japan Inst. Met. 21, 237 (1980).Google Scholar
111. Rozner, A.G. and Wasilewski, R.J., J. Inst. Met. 94, 69 (1966).Google Scholar
112. Aoki, K. and Izumi, O., Trans. Japan Inst. Met. 19, 203 (1978).Google Scholar
113. Sainfort, G., Fragilite et Effects de L'Irradiation. Presses Universitaires de France, 187 (1967).Google Scholar
114. Kuruvilla, A.K. and Stoloff, N.S., unpublished (1984).Google Scholar
115. Liu, C.T. and White, C.W., Oak Ridge National Lab, unpublished (1984).Google Scholar