The Al−Sc (Aluminum-Scandium) system

1. O.P. Naumkin, V.T. Terekhova and E.M. Savitskii,Izv. Akad. Nauk SSSR Met., No. 4, p 176–182 (1965); translated inRuss. Met., No. 4, p 128–136 (1965). Also see E.M. Savitskii, V.F. Terekhova, I.V. Burov and O.P. Naumkin, inRare Earth Research III, Proc. Fourth Conf. (1964), L. Eyring, Ed., Gordon and Breach, Science Publishers, Inc., NY, p 301–319 (1965).

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2. P.I. Kripyakevich and I.I. Zalutskii, in E.M. Savitskii and V.F. Terekhova, Eds.,Voprosy Teorii i Primeniniya Redkozemelynkh Metallov., Akad. Nauk SSSR, Moscow, p 144–145 (1964); translated as U.S. Dept. Commerce JPRS-28849, p 188–190 (1964).

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3. V.N. Rechkin, L.K. Lamikhov and T.L. Samsonova,Kristallografiya, 9, p 405–408 (1964); translated inSov. Phys.—Crystallogr., 9, p 325–327 (1964).

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4. A.E. Dwight, U.S. At. Energy Comm., ANL-6330, p 156–158 (1960).

5. O. Schob and E. Parthé,Acta Cryst., 19, p 214–224 (1965).

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Additional References

1. B.T. Matthias, T.H. Geballe and V.B. Compton, Superconductivity,Rev. Modern Phys., 35, p 1–22 (1963). (Al₂Sc was found to have the Cu₂Mg-type structure [C15] and was not superconducting above 1.02 K)

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2. I.I. Zalutskii and P.I. Kripyakevich, RAl₃ Compounds in Rare Earth—Aluminum Systems and Their Crystal Structures,Kristallografiya, 12(3), p 394–397 (1967) in Russian; translated asSov. Phys.—Crystallogr., 12(3), p 341–343 (1967). (Confirmed the AuCu₃ structure for Al₃Sc, witha=0.4105 nm)

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3. S. Eymond and E. Parthé, Sc₂Al with Ni₂In Structure Type,J. Less-Common Met., 19, p 441–443 (1969). (Crystal data given in Crystal Structures table)

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4. M.E. Drits, E.S. Kadaner, T.V. Dobatkina and N.I. Turkina, Scandium-Aluminum Interactions in the Aluminum-Rich Side of the Al−Sc System,Izv. Akad. Nauk SSSR Met., No. 4, p 113–217 (1973) in Russian; translated asRuss. Met., No. 4, p 152–154 (1973). (A eutectic-type reaction was observed at 655°C with a Sc solid-solubility of 0.22 wt.% at 640°C. Purity of Sc, 99.875 wt.%, is given as possible explanation of difference with Fig. 1, where purity of 99.5 wt.% Sc was used) See Fig. 2.

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5. C.T. Horovitz, Editor,Scandium; Its Occurrence, Chemistry, Physics, Metallurgy, Biology and Technology, Academic Press, London (1975). (Includes a brief review of the Al−Sc phase diagram and crystal structure properties of its intermetallic compounds)

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6. M. Očko, E. Babić, R. Krsmik, E. Girt and B. Leontić, Some Properties of AlSc Solid Solutions,J. Phys. F Met. Phys., 6(5), p 703–707 (1976). (Solid solutions up to 3.28 at.% Sc in Al were prepared by rapid quenching. The lattice parameters, residual resistivities and microhardness of Al−Sc (0 to 3.28 at.%) alloys are reported)

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7. M. Očko, E. Babić and V. Zlatić, Changes of the Lattice Parameter in Al 3d Alloys Due to the Virtual Bound State,Solid State Commun., 18, p 705–708 (1976). (Enhanced solid solubility of up to 3.2 at.% Sc in Al was obtained by rapid quenching. Lattice parameters were reported) See Fig. 3.

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