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Stacking fault energies of fcc fe-Ni alloys by x-ray diffraction line profile analysis

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Abstract

The stacking fault energies of the fee alloy series Fe-28 Ni to pure Ni were investigated using X-ray diffraction line profile analysis. A minimum stacking fault energy of about 70 mJ/m2 occurs at the approximate composition of Fe-40 pct Ni. From this point, the lower nickel alloys rapidly increase to a very high stacking fault energy, estimated to be 200 mJ/m2, while the energies of the high Ni alloys rise linearly to the Ni value of 214 mJ/m2. Anomalous reductions of the lattice parameter after cold work were found for the low nickel alloys; this was interpreted as evidence for Fe3Ni ordering and corrections to the stacking fault energy were made.

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Authors and Affiliations

  1. Cryogenics Division, National Bureau of Standards, Institute for Basic Standards, 80302, Boulder, CO

    Raymond E. Schramm (Physicist) & Richard P. Reed (Supervisory Metallurgist)

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  1. Raymond E. Schramm
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  2. Richard P. Reed
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Schramm, R.E., Reed, R.P. Stacking fault energies of fcc fe-Ni alloys by x-ray diffraction line profile analysis. Metall Trans A 7, 359–363 (1976). https://doi.org/10.1007/BF02642831

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  • DOI: https://doi.org/10.1007/BF02642831

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