TY - JOUR
T1 - Multiscale nanoindentation modelling of concentrated solid solutions : A continuum plasticity model
AU - Frydrych, K.
AU - Dominguez-Gutierrez, F. J.
AU - Alava, M. J.
AU - Papanikolaou, S.
N1 - Funding Information:
We acknowledge support from the European Union Horizon 2020 research and innovation program under grant agreement no. 857470 and from the European Regional Development Fund via the Foundation for Polish Science International Research Agenda PLUS program, Poland grant No. MAB PLUS/2018/8 . We acknowledge the computational resources provided by the High Performance Cluster at the National Centre for Nuclear Research in Poland. Karol Frydrych acknowledges fruitful discussions with prof. Katarzyna Kowalczyk-Gajewska from IPPT PAN.
| openaire: EC/H2020/857470/EU//NOMATEN
PY - 2023/6
Y1 - 2023/6
N2 - Recently developed single-phase concentrated solid-solution alloys (CSAs) contain multiple elemental species in high concentrations with different elements randomly arranged on a crystalline lattice. These chemically disordered materials present excellent physical properties, including high-temperature thermal stability and hardness, with promising applications to industries at extreme operating environments. The aim of this paper is to present a continuum plasticity model accounting for the first time for the behaviour of a equiatomic five-element CSA, that forms a face-centred cubic lattice. The inherent disorder associated with the lattice distortions caused by an almost equiatomic distribution of atoms, is captured by a single parameter α that quantifies the relative importance of an isotropic plastic contribution to the model. This results in multiple plasticity mechanisms that go beyond crystallographic symmetry-based ones, common in the case of conventional single element metals. We perform molecular dynamics simulations of equiatomic CSAs: NiFe, NiFeCr, NiFeCrCo, and Cantor alloys to validate the proposed continuum model which is implemented in the finite element method and applied to model nanoindentation tests for three different crystallographic orientations. We obtain the representative volume element model by tracking the combined model yield surface.
AB - Recently developed single-phase concentrated solid-solution alloys (CSAs) contain multiple elemental species in high concentrations with different elements randomly arranged on a crystalline lattice. These chemically disordered materials present excellent physical properties, including high-temperature thermal stability and hardness, with promising applications to industries at extreme operating environments. The aim of this paper is to present a continuum plasticity model accounting for the first time for the behaviour of a equiatomic five-element CSA, that forms a face-centred cubic lattice. The inherent disorder associated with the lattice distortions caused by an almost equiatomic distribution of atoms, is captured by a single parameter α that quantifies the relative importance of an isotropic plastic contribution to the model. This results in multiple plasticity mechanisms that go beyond crystallographic symmetry-based ones, common in the case of conventional single element metals. We perform molecular dynamics simulations of equiatomic CSAs: NiFe, NiFeCr, NiFeCrCo, and Cantor alloys to validate the proposed continuum model which is implemented in the finite element method and applied to model nanoindentation tests for three different crystallographic orientations. We obtain the representative volume element model by tracking the combined model yield surface.
KW - Crystal plasticity
KW - Finite element method
KW - High entropy alloys
KW - Molecular dynamics
KW - Nanoindentation
UR - http://www.scopus.com/inward/record.url?scp=85151570563&partnerID=8YFLogxK
U2 - 10.1016/j.mechmat.2023.104644
DO - 10.1016/j.mechmat.2023.104644
M3 - Article
AN - SCOPUS:85151570563
SN - 0167-6636
VL - 181
SP - 1
EP - 12
JO - MECHANICS OF MATERIALS
JF - MECHANICS OF MATERIALS
M1 - 104644
ER -