@Comment { \documentclass{article} \usepackage{url} \begin{document} This Model originally published in \cite{OpenKIM-MO:677715648236:000a} is archived in \cite{OpenKIM-MO:677715648236:000, OpenKIM-MD:120291908751:005, tadmor:elliott:2011, elliott:tadmor:2011}. \bibliographystyle{vancouver} \bibliography{kimcite-MO_677715648236_000.bib} \end{document} } @Misc{OpenKIM-MO:677715648236:000, author = {Giovanni Bonny and D. Terentyev and Roberto C Pasianot and Samuel Poncé and A. Bakaev}, title = {{EAM} potential ({LAMMPS} cubic hermite tabulation) for the {F}e-{N}i-{C}r system developed by {B}onny et al. (2011) v000}, doi = {10.25950/9ebbd935}, howpublished = {OpenKIM, \url{https://doi.org/10.25950/9ebbd935}}, keywords = {OpenKIM, Model, MO_677715648236_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:677715648236:000a, abstract = {Austenitic stainless steels are commonly used materials for in-core components of nuclear light water reactors. In service, such components are exposed to harsh conditions: intense neutron irradiation, mechanical and thermal stresses, and aggressive corrosion environment which all contribute to the components' degradation. For a better understanding of the prevailing mechanisms responsible for the materials degradation, large-scale atomistic simulations are desirable. In this framework we developed an embedded atom method type interatomic potential for the ternary FeNiCr system to model movement of dislocations and their interaction with radiation defects. Special attention has been drawn to the Fe–10Ni–20Cr alloy, whose properties were ensured to be close to those of 316L austenitic stainless steel. In particular, the stacking fault energy and elastic constants are well reproduced. The fcc phase for the Fe–10Ni–20Cr random alloy was proven to be stable in the temperature range 0–900 K and under shear strain up to 5%. For the same alloy the stable glide of screw dislocations and stability of Frank loops was confirmed.}, author = {Bonny, G and Terentyev, D and Pasianot, R C and Ponc{\'{e}}, S and Bakaev, A}, doi = {10.1088/0965-0393/19/8/085008}, journal = {Modelling and Simulation in Materials Science and Engineering}, month = {nov}, number = {8}, pages = {085008}, publisher = {{IOP} Publishing}, title = {Interatomic potential to study plasticity in stainless steels: the {FeNiCr} model alloy}, url = {https://doi.org/10.1088/0965-0393/19/8/085008}, volume = {19}, year = {2011}, }