Multi-phase ELAStic Aggregates (MELASA) software tool for modeling anisotropic elastic properties of lamellar composites

0517187 - ÚFM 2021 RIV NL eng J - Journal Article
Friák, Martin - Lago, D. - Koutná, N. - Holec, D. - Rebok, T. - Šob, Mojmír
Multi-phase ELAStic Aggregates (MELASA) software tool for modeling anisotropic elastic properties of lamellar composites.
Computer Physics Communications. Roč. 247, FEB (2020), č. článku 106863. ISSN 0010-4655. E-ISSN 1879-2944
R&D Projects: GA ČR(CZ) GA17-22139S; GA MŠMT LM2015069
Institutional support: RVO:68081723
Keywords : Anisotropy * Coherency * Composites * Elasticity * Superlattices * Web application
OECD category: Condensed matter physics (including formerly solid state physics, supercond.)
Impact factor: 4.390, year: 2020
Method of publishing: Limited access
https://www.sciencedirect.com/science/article/pii/S0010465519302504?via%3Dihub

We introduce a new web-based tool called MELASA (Multi-phase ELAStic Aggregates), open-access available at https://melasa.cerit-sc.cz, for computations and visualizations of anisotropic elastic properties of lamellar (nano-)composites. MELASA implements a linear-elasticity method by Grimsditch and Nizzoli (1986), originally developed for superlattices of any symmetry. Our tool may be used for computation of anisotropic elastic properties of a specific type of periodically separated lamellar (nano-)composites using matrices of elastic stiffnesses of co-existing phases as an input. Elastic properties are visualized in the form of directional dependencies of selected elastic characteristics (Young's modulus and linear compressibility). MELASA further generalizes the Grimsditch–Nizzoli approach, which was originally formulated for only two phases, to multiple-phase composites. Additionally, our implementation allows for treating internal rotations of local coordination systems corresponding to the natural set of coordinates that match directional vectors of unit cell defining crystal lattice within the co-existing phases. Fe–Al-based superalloy nanocomposites are employed as a numerical example of superlattices with the input and output elastic stiffnesses determined by quantum-mechanical calculations. In particular, three different atomic configurations of interfaces in superlattices containing the ordered Fe3Al phase and a disordered Fe–Al phase with 18.75at.%Al (modeled by a special quasi-random structure, SQS) are considered. They differ by relative positions of sublattices in Fe3Al (an antiphase-like shift) and/or atomic planes in Fe-18.75at.%Al with respect to the interface (a circular/cyclic shift). Program summary: Program title: MELASA Program files doi: http://dx.doi.org/10.17632/rzc2yd2rvc.1 Licensing provisions: MIT license Programming language: JavaScript Nature of problem: Computations and visualizations of anisotropic elastic properties of lamellar (nano-)composites/superlattices Solution method: Implementation of a linear-elasticity method by M. Grimsditch and F. Nizzoli [1], originally derived for superlattices of any symmetry. MELASA computes anisotropic elastic properties of a specific type of periodically separated lamellar (nano-)composites using matrices of elastic stiffnesses of co-existing phases as input. Elastic properties are visualized in the form of directional dependencies of selected elastic characteristics (Young's modulus and linear compressibility). Additional comments including restrictions and unusual features: MELASA generalizes the Grimsditch–Nizzoli approach, which was originally formulated for only two phases, to multiple-phase composites. Additionally, our implementation allows for treating internal rotations of local coordination systems corresponding to the natural set of coordinates that match directional vectors of unit cell defining crystal lattice within the co-existing phases.
Permanent Link: http://hdl.handle.net/11104/0308222