The Fe−Ni (Iron-Nickel) system

1. E. Schürmann and J. Brauckmann,Arch. Eisenhüttenwes., 48(1), p 3–7 (1977).

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Additional References

1. Y. Calvayrac and M. Fayard, Comportement Des Alliages Nickel-Fer De Compositions Proches De 75-25 Au Voisinage De La Temperature De Transformation Ordre-Desordre (Behavior of Ni−Fe alloys with Compositions Near 75-25 in the Neighborhood of the Order-Disorder Transformation Temperature),Mat. Res. Bull., 7, p 891–902 (1972) in French. (Claimed that the order-disorder transformation, in the neighborhood of FeNi₃, apparently violates the Gibbs-Konovalov theorem and has no congruent transformation at its maximum)

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2. F.J. Bartis, What Causes Phase Coexistence in Ordering Alloys?,Acta Metall., 26, p 879–881 (1978). (Attempted to explain the results of [2] for FeNi₃ by the action of stresses around dislocations and point defects)

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3. J.M. Larrain and H.H. Kellogg, Use of Chemical Species for Correlation of Solution Properties,Calculations of Phase Diagrams and Thermochemistry of Alloy Phases, TMS/AIME, Warrendale, PA 15086, p 130–144 (1979). (Calculation of Fe−Ni phase diagram and thermodynamic properties)

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4. J.K. van Deen and F. van der Woude, Evidence for Direct Order-Disorder Transition in Ni₇₃Fe₂₇,Phys. Rev. B, 20(1), p 296–298 (1979). (Using the Mössbauer effect, found no two phase region at the maximum of the order-disorder, in contradiction to [2])

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5. J.K. van Deen and F. van der Woude, Phase Diagram of the Order-Disorder transition in Ni₃Fe,J. Phys., 41 (no. 1 suppl.) C1, p 367–368 (1980). (Using the Mössbauer effect, found no two phase region at the maximum of the order-disorder, in contradiction to [2]) (See [5])

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6. P.L. Gruzin, Yu.L. Rodionov and V.A. Pryakhin, O Diagramme Sostoyaniya G. Ts. K. Zhelezo-Nikelevikh Splavov (Phase Diagram of fcc Lattices of Iron-Nickel Alloys),Dokl. Akad. Nauk SSSR, 251(6), p 1384–1388 (1980) in Russian. (The effect of 3–5 MeV electron irradiation of the γ phase in the 20 to 50% nickel region caused these distributions of atoms, producing Ni-poor and Ni-rich areas. An equilibrium phase diagram for fcc Fe−Ni in the range 20–55 at.% Ni was proposed)

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7. A.D. Romig, Jr. and J.I. Goldstein, Determination of the Fe−Ni and Fe−Ni−P Phase Diagrams at Low Temperatures (700 to 300°C),Metall. Trans. A, 11(7), p 1151–1159 (1980). (The limit of the α+γ two-phase field in the Fe−Ni phase diagram between 700 and 300 °C was determined by electron microprobe and STEM techniques) See Fig. 2

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