Accounting for lattice coherency in a two-phase elastic-plastic self-consistent model for nickel-based superalloys
Artikel i vetenskaplig tidskrift, 2018

A 2-site elastic-plastic self-consistent (EPSC) model is developed and implemented in order to account for crystallographic texture development and grain morphology evolution under strong correlations between neighbor grains of different phases, both in space and orientation. Predictions of the model adequately fit the published in situ neutron diffraction data for nickel-based superalloys at ambient and elevated temperatures, in whichγandγ'phases exhibit exact cube-cube orientation relationship. Comparison with 2-site model (small strain algorithm, non-rotation scheme) and 1-site model (finite strain algorithm, co-rotation scheme) has been made, and the result shows that the present 2-site model (finite strain algorithm, rotation scheme) leads to better predictions in lattice strain evolution where both rotation of crystal lattice and correlation between inclusions are accounted for, especially when the applied strain is larger than 0.02 for transverse direction and0.05∼0.18for axial direction for the materials studied in this work. Based on a systematic study on the effects of grain-grain interaction and total grain number on the homogenized results, we found that transverse lattice strains ofγ(200) and/orγ'(100) are sensitive to the interplay betweenγ-γ'interaction and evolution of grain orientation distribution with deformation, while that ofγ(220) andγ'(110) are sensitive to the initial crystallographic texture.

Nickel-based superalloy

Two-phase polycrystal

2-Site elastic-plastic self-consistent model

In situ neutron diffraction

Finite strain


Hongjia Li

Chalmers, Fysik, Materialens mikrostruktur

China Academy of Engineering Physics

Magnus Ekh

Chalmers, Industri- och materialvetenskap, Material- och beräkningsmekanik

Magnus Hörnqvist Colliander

Chalmers, Fysik, Materialens mikrostruktur

Fredrik Larsson

Chalmers, Industri- och materialvetenskap, Material- och beräkningsmekanik

International Journal of Plasticity

0749-6419 (ISSN)

Vol. 110 248-271


Teknisk mekanik

Metallurgi och metalliska material

Multidisciplinär geovetenskap



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