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MM: Fachverband Metall- und Materialphysik

MM 11: Topical Session: Defects of Defects

MM 11.7: Topical Talk

Dienstag, 18. März 2025, 12:30–13:00, H10

Atomistic structure of fcc-fcc interface in pure iron and in nanomultilayers: insight from atommistic modeling — •Helene Zapolsky¹, Gilles Demange², Yuri Borges Gomes Lima³, Anastasiai Titova⁴, and Renaud Patte⁵ — ¹GPM, UMR 6634 University of Rouen, France — ²GPM, UMR 6634 University of Rouen, France — ³GPM, UMR 6634 University of Rouen, France — ⁴GPM, UMR 6634 University of Rouen, France — ⁵GPM, UMR 6634 University of Rouen, France

Very great interest in the structure of interphase interfaces between fcc and bcc crystals has historically arisen due to their technological importance in steels. These interfaces also play a crucial role in metallic nanomultilayers (NMLs), where the presence of numerous semi-coherent interfaces leads to a broad spectrum of novel and remarkable properties. One such system, the Cu/Mo NML, holds promise for thermal management applications due to the combination of copper's excellent thermal conductivity and molybdenum's low coefficient of thermal expansion. In these systems, defects at the fcc/bcc interface have a profound impact the thermal properties of the materials. Recently, the Quasiparticle Approach (QA), based on the phase-field methodology, has emerged as a powerful computational tool for modeling and predicting the atomic-scale structure of various interfaces. In this work, we employ atomistic modeling to examine the detailed structure of the fcc/bcc interface, exploring the relationship between this structure and the mode of interface propagation during displacive phase transformations in pure iron and in Cu/Mo NML.

Keywords: fcc/bcc interface; atomistic modeling; dislocations; displacive phase transformation; nanomultilayers