@Comment { \documentclass{article} \usepackage{url} \begin{document} This Model originally published in \cite{OpenKIM-MO:871937946490:000a} is archived in \cite{OpenKIM-MO:871937946490:000, OpenKIM-MD:120291908751:005, tadmor:elliott:2011, elliott:tadmor:2011}. \bibliographystyle{vancouver} \bibliography{kimcite-MO_871937946490_000.bib} \end{document} } @Misc{OpenKIM-MO:871937946490:000, author = {Laurent K. BĂ©land and Chenyang Lu and Yuri N. Osetskiy and German D. Samolyuk and A. Caro and Lumin Wang and Roger E. Stoller}, title = {{EAM} potential ({LAMMPS} cubic hermite tabulation) for the {N}i-{C}o system developed by {B}eland et al. (2016) v000}, doi = {10.25950/9884d9d7}, howpublished = {OpenKIM, \url{https://doi.org/10.25950/9884d9d7}}, keywords = {OpenKIM, Model, MO_871937946490_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:871937946490:000a, abstractnote = {Alloying of Ni with Fe or Co reduces primary damage production under ion irradiation. Similar results have been obtained from classical molecular dynamics simulations of 1, 10, 20, and 40 keV collision cascades in Ni, NiFe, and NiCo. In all cases, a mix of imperfect stacking fault tetrahedra, faulted loops with a 1/3 $\langle 111\rangle$ Burgers vector, and glissile interstitial loops with a 1/2 $\langle 110\rangle$ Burgers vector were formed, along with small sessile point defect complexes and clusters. Primary damage reduction occurs by three mechanisms. First, Ni-Co, Ni-Fe, Co-Co, and Fe-Fe short-distance repulsive interactions are stiffer than Ni-Ni interactions, which lead to a decrease in damage formation during the transition from the supersonic ballistic regime to the sonic regime. This largely controls final defect production. Second, alloying decreases thermal conductivity, leading to a longer thermal spike lifetime. The associated annealing reduces final damage production. These two mechanisms are especially important at cascades energies less than 40 keV. Third, at the higher energies, the production of large defect clusters by subcascades is inhibited in the alloys. A number of challenges and limitations pertaining to predictive atomistic modeling of alloys under high-energy particle irradiation are discussed.}, author = {B{\'{e}}land, Laurent Karim and Lu, Chenyang and Osetskiy, Yuri N. and Samolyuk, German D. and Caro, Alfredo and Wang, Lumin and Stoller, Roger E.}, doi = {10.1063/1.4942533}, issn = {0021-8979}, journal = {Journal of Applied Physics}, month = {feb}, number = {8}, place = {United States}, title = {Features of primary damage by high energy displacement cascades in concentrated {N}i-based alloys}, url = {https://www.osti.gov/biblio/1239766}, volume = {119}, year = {2016}, }