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dc.contributor.authorBaker, I.
dc.contributor.authorZheng, R.
dc.contributor.authorSaxey, David
dc.contributor.authorKuwano, S.
dc.contributor.authorWittmann, M.
dc.contributor.authorLoudis, J.
dc.contributor.authorPrasad, K.
dc.contributor.authorLiu, Z.
dc.contributor.authorMarceau, R.
dc.contributor.authorMunroe, P.
dc.contributor.authorRinger, S.
dc.identifier.citationBaker, I. and Zheng, R. and Saxey, D. and Kuwano, S. and Wittmann, M. and Loudis, J. and Prasad, K. et al. 2009. Microstructural evolution of spinodally formed Fe<inf>35</inf>Ni<inf>15</inf>Mn<inf>25</inf>Al<inf>25</inf>. Intermetallics. 17 (11): pp. 886-893.

The microstructural evolution of a b.c.c.-based, spinodally formed alloy Fe35Ni15Mn25Al25 has been studied as a function of annealing time at 550 °C using atom probe tomography and transmission electron microscopy, including energy-filtered imaging. The sizes, crystal structures, orientation relationships and compositions of the phases present were determined as a function of annealing time. The hardness showed complicated behavior as a function of annealing time, consisting of initial hardening, followed by softening and finally, by a rapid hardening behavior. The hardness is controlled both by the coarsening of the spinodally formed phases, and the precipitation and growth of ß-Mn structured particles. © 2009 Elsevier Ltd. All rights reserved.

dc.publisherELSEVIER Ltd
dc.titleMicrostructural evolution of spinodally formed Fe<inf>35</inf>Ni<inf>15</inf>Mn<inf>25</inf>Al<inf>25</inf>
dc.typeJournal Article
curtin.departmentJohn de Laeter CoE in Mass Spectrometry
curtin.accessStatusFulltext not available

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