Electron Microscopy Study of Hypostoichiometric Fe-Pd Nanocomposites Resulting from Combined Reactions Thermomechanical Processing

Elizabeth D. Cantando; Gerard M. Ludtka; Gail Mackiewicz-Ludtka; William A. Soffa

doi:10.4028/www.scientific.net/SSP.172-174.356

Paper Titles

Thermal Embrittlement of a Lean Grade of Duplex Stainless Steel: Alloy 2003
p.331

Study by Differential Thermal Analysis of Reverse Spinodal Transformation in 15-5 PH Alloy.
p.338

Tweed and Nanoscale Cubic / Tetragonal Phase Mixtures in Decomposing Alloys: the Pseudospinodal Concept
p.344

Duplex Stainless Steel Microstructural Developments as Model Microstructures for Hot Ductility Investigations
p.350

Electron Microscopy Study of Hypostoichiometric Fe-Pd Nanocomposites Resulting from Combined Reactions Thermomechanical Processing
p.356

Influence of High Magnetic Field on Ferrite Transformation in Fe-C Base Alloys
p.362

Ferrite Formation Above the Ae₃ in a Medium-Carbon Steel
p.372

Influence of Crystallography on Nucleation of Ferrite Precipitates at Austenite Grain Boundary Corners in a Co-15Fe Alloy
p.378

Phase Transformation Near Dislocations and Cracks
p.384

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Electron Microscopy Study of Hypostoichiometric Fe-Pd Nanocomposites Resulting from Combined Reactions Thermomechanical Processing

Abstract:

Hypostoichiometric Fe-Pd binary alloys (35-45 at% Pd) were severely deformed (>90%) and subsequently aged to induce concomitant recrystallization, precipitation, and ordering. This thermomechanical processing strategy was articulated by Hornbogen [1] over thirty years ago. The resulting exchange-coupled ferromagnets contain ferrite precipitates and a complex metastable two-phase lamellar transformation product comprised of ordered L1₀ and a metastable FCC phase. The later duplex microconstituent is suggested to form in conjunction with a so-called pseudospinodal reaction [2] involving emerging cubic and tetragonal phases, whereby phase separation and ordering result from continuous changes in composition and a reduction in symmetry, cubic to tetragonal. The deformation texture of the parent austenite is substantially retained in the transformation product, resulting in anisotropy of the magnetic properties as determined by magnetometry (VSM). This paper presents electron microscopy results elucidating the crystallography and morphology of the phase mixtures including HREM. Magnetic field annealing is also included as a branch of our thermomechanical processing strategy, and we discuss the influence of the external fields on recrystallization, precipitation, and ordering.