@Comment { \documentclass{article} \usepackage{url} \begin{document} This Model originally published in \cite{OpenKIM-MO:820335782779:000a} is archived in \cite{OpenKIM-MO:820335782779:000, OpenKIM-MD:120291908751:005, tadmor:elliott:2011, elliott:tadmor:2011}. \bibliographystyle{vancouver} \bibliography{kimcite-MO_820335782779_000.bib} \end{document} } @Misc{OpenKIM-MO:820335782779:000, author = {Diana Farkas and A. Caro}, title = {{EAM} potential ({LAMMPS} cubic hermite tabulation) for the {F}e-{N}i-{C}r-{C}o-{A}l system developed by {F}arkas and {C}aro (2020) v000}, doi = {10.25950/8c495c7e}, howpublished = {OpenKIM, \url{https://doi.org/10.25950/8c495c7e}}, keywords = {OpenKIM, Model, MO_820335782779_000}, publisher = {OpenKIM}, year = 2022, } @Misc{OpenKIM-MD:120291908751:005, author = {Stephen M. Foiles and Michael I. Baskes and Murray S. Daw and Steven J. Plimpton}, title = {{EAM} {M}odel {D}river for tabulated potentials with cubic {H}ermite spline interpolation as used in {LAMMPS} v005}, doi = {10.25950/68defa36}, howpublished = {OpenKIM, \url{https://doi.org/10.25950/68defa36}}, keywords = {OpenKIM, Model Driver, MD_120291908751_005}, publisher = {OpenKIM}, year = 2018, } @Article{tadmor:elliott:2011, author = {E. B. Tadmor and R. S. Elliott and J. P. Sethna and R. E. Miller and C. A. Becker}, title = {The potential of atomistic simulations and the {K}nowledgebase of {I}nteratomic {M}odels}, journal = {{JOM}}, year = {2011}, volume = {63}, number = {7}, pages = {17}, doi = {10.1007/s11837-011-0102-6}, } @Misc{elliott:tadmor:2011, author = {Ryan S. Elliott and Ellad B. Tadmor}, title = {{K}nowledgebase of {I}nteratomic {M}odels ({KIM}) Application Programming Interface ({API})}, howpublished = {\url{https://openkim.org/kim-api}}, publisher = {OpenKIM}, year = 2011, doi = {10.25950/ff8f563a}, } @Article{OpenKIM-MO:820335782779:000a, abstract = {A set of embedded atom model (EAM) interatomic potentials was developed to represent highly idealized face-centered cubic (FCC) mixtures of Fe--Ni--Cr--Co--Al at near-equiatomic compositions. Potential functions for the transition metals and their crossed interactions are taken from our previous work for Fe--Ni--Cr--Co--Cu [D. Farkas and A. Caro: J. Mater. Res. 33 (19), 3218--3225, 2018], while cross-pair interactions involving Al were developed using a mix of the component pair functions fitted to known intermetallic properties. The resulting heats of mixing of all binary equiatomic random FCC mixtures not containing Al is low, but significant short-range ordering appears in those containing Al, driven by a large atomic size difference. The potentials are utilized to predict the relative stability of FCC quinary mixtures, as well as ordered L12 and B2 phases as a function of Al content. These predictions are in qualitative agreement with experiments. This interatomic potential set is developed to resemble but not model precisely the properties of this complex system, aiming at providing a tool to explore the consequences of the addition of a large size-misfit component into a high entropy mixture that develops multiphase microstructures.}, author = {Farkas, Diana and Caro, Alfredo}, day = {01}, doi = {10.1557/jmr.2020.294}, issn = {2044-5326}, journal = {Journal of Materials Research}, month = {nov}, number = {22}, pages = {3031-3040}, title = {Model interatomic potentials for {Fe--Ni--Cr--Co--Al} high-entropy alloys}, url = {https://doi.org/10.1557/jmr.2020.294}, volume = {35}, year = {2020}, }