Abstract
While there are nearly 300 high-melting-temperature intermetallic compounds, numerous factors limit the commercial viability of these materials for structural applications. Once the desirability of a material’s crystal structure has been determined, the engineer must then focus on the compound’s oxidation and corrosion resistance, its cost and any associated environmental hazards that may diminish its practical value. The final engineering limitations are imposed by process capabilities, which must be improved if high-temperature intermetallics are to one day emerge from the laboratory.
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References
M. Gell, D.N. Duhl, D.K. Gupta and K.D. Sheffler, Journal of Metals, 39(11) (1987).
H. Inouye, Niobium—Proceedings of the International Symposium, ed. H. Stuart (1981), p. 615.
A.J. Meyer, Jr., and G.C. Deutsch, Cermets, ed. J.R. Tinklepaugh and W.B. Crandall (New York: W.B. Reinhold Publishing Corporation, 1960), pp. 196–207.
Intermetallic Compounds, ed. J.H. Westbrook (New York: John Wiley and Sons, Inc., 1967).
Ordered Alloys—Structural Application and Physical Metallurgy, ed. B.H. Kear, proceedings of the Third Bolton Landing Conference, September 1969.
R. Flukiger, Superconductor Material Science Metallurgy, Fabrication and Applications, ed. S. Foner and Brian B. Schwartz (Plenum Press, 1981), pp. 511–604.
J. Booker, R.M. Paine and A.J. Stonehouse, “Investigation of Intermetallic Compounds for Very High Temperature Applications,” WADD TR 60-889 (1961).
H.A. Lipsitt, High Temperature Ordered Intermetallic Alloys,ed. C.C. Koch et al. (Pittsburgh, PA: MRS, 1985), pp. 351–364.
CM. Adam et al., Development of Iron Aluminide, AFWAL/MLLM contract F33615-84-C-5110, Pratt & Whitney.
C.C. Law and M.J. Blackburn, Rapidly Solidified Lightweight Durable Disk Material, AFWAL/MLLM contract F33615-84-C-5067, Pratt & Whitney.
I. Baker and P.R. Munroe, “Improving Intermetallic Ductility and Toughness,” Journal of Metals, 40(2) (1988), pp. 28–31.
J.H. Wernick, op. cit. 4, p. 197.
E.S. Fisher, Metallurgical Transactions, 11 (1980), p. 103.
A.E. Gemma, B.S. Langer and G. Leverant, Thermal Fatigue of Materials and Components, ASTM STP 612, ed. D. Spera and D. Mowbrag (Philadelphia, PA: ASTM, 1976).
K. Vedula et al., op. cit. 8, pp. 411–421.
D.P. Pope and S.S. Ezz, Int. Met.. Rev., 29 (1984), p. 136.
D.M. Shah and D.N. Duhl, Superalloys 1984, ed. M. Gell et al. (Warrendale, PA: TMS, 1984), pp. 105–114.
D.L. Anton and D.M. Shah, High-Temperature Ordered Intermetallic Alloys II, ed. N.S. Stoloff, C.C. Koch, CT. Liu and O. Izumi (Pittsburgh, PA: MRS, 1987).
J.E. Dorn, Creep and Recovery, (Metals Park, OH: ASM, 1957).
J.E. Dorn, Creep and Fracture of Metals at High Temperatures (London: National Physical Laboratory, 1956).
V.N. Agafonov et al., Vstn. Mosk. Univ. Khim, 16 (1975), p. 121.
S.M. Russel, C.C Law, M.J. Blackburn, P.C. Clapp and D.M. Pease, Lightweight Disk Alloy Development, AFWAL/MLLM contract F33615-86-C-5037, Pratt & Whitney.
L. Brewer, Alloying, ed. J. Walter et al. (Metals Park, OH: ASM, 1988).
K. Aoki and O. Izimi, J. Japan Inst. Met.., 43 (1979), pp. 1190.
H.H. Stadelmaier and L.J. Hvelter, ActaMet., 6 (1958), pp. 367–370.
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Anton, D.L., Shah, D.M., Duhl, D.N. et al. Selecting high-temperature structural intermetallic compounds: The engineering approach. JOM 41, 12–17 (1989). https://doi.org/10.1007/BF03220324
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DOI: https://doi.org/10.1007/BF03220324