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dc.contributorUniv Mayor Chile, Fac Ciencias, Ctr Nanotecnol Aplicada, Chilees
dc.contributor.authorTramontina, DR.
dc.contributor.authorDeluigi, OR.
dc.contributor.authorPinzón, R.
dc.contributor.authorRojas-Núñez, J.
dc.contributor.authorValencia, FJ.
dc.contributor.authorPasianot, RC.
dc.contributor.authorBaltazar, SE.
dc.contributor.authorGonzalez, RI. [Univ Mayor Chile, Fac Ciencias, Ctr Nanotecnol Aplicada, Chile]
dc.contributor.authorBringa, EM. [Univ Mayor Chile, Fac Ciencias, Ctr Nanotecnol Aplicada, Chile]
dc.date.accessioned2024-03-22T17:24:52Z
dc.date.available2024-03-22T17:24:52Z
dc.date.issued2023-08
dc.identifier.citationTramontina, D. R., Deluigi, O. R., Pinzón, R., Rojas-Nunez, J., Valencia, F. J., Pasianot, R. C., ... & Bringa, E. M. (2023). Probing radiation resistance in simulated metallic core–shell nanoparticles. Computational Materials Science, 227, 112304.es
dc.identifier.issn0927-0256
dc.identifier.issneISSN 1879-0801
dc.identifier.otherWOS:001017257600001
dc.identifier.otherSCOPUS_ID:85160860504
dc.identifier.urihttps://repositorio.umayor.cl/xmlui/handle/sibum/9497
dc.identifier.urihttps://doi-org.bibliotecadigital.umayor.cl:2443/10.1016/j.commatsci.2023.112304
dc.identifier.urihttps://doi.org/10.1016/j.commatsci.2023.112304
dc.description.abstractWe present molecular dynamics (MD) simulations of radiation damage in Fe nanoparticles (NP) and bimetallic FeCu core-shell nanoparticles (CSNP). The CSNP includes a perfect body-centered cubic (bcc) Fe core coated with a face-centered cubic (fcc) Cu shell. Irradiation with Fe Primary Knock-on Atoms (PKA) with energies between 1 and 7 keV leads to point defects, without clustering beyond divacancies and very few slightly larger vacancy clusters, and without interstitial clusters, unlike what happens in bulk at the same PKA energies. The Fe-Cu interface and shell can act as a defect sink, absorbing radiation-induced damage and, therefore, the final number of defects in the Fe core is significantly lower than in the Fe NP. In addition, the Cu shell substantially diminishes the number of sputtered Fe atoms, acting as a barrier for recoil ejection. Structurally, the Cu shell responds to the stress generated by the collision cascade by creating and destroying stacking faults across the shell width, which could also accommodate further irradiation defects. We compare our MD results to Monte Carlo Binary Collision Approximation (BCA) simulations using the SRIM code, for the irradiation of an amorphous 3-layer thin film with a thickness equal to the CSNP diameter. BCA does not include defect recombination, so the number of Frenkel pairs is significantly higher than in MD, as expected. Sputtering yield (Y) is underestimated by BCA, which is also expected since the simulation is for a thin film at normal incidence. We also compare MD defect production to bulk predictions of the analytic Athermal Recombination Corrected Displacements Per Atom (arc-dpa) model. The number of vacancies in the Fe core is only slightly lower than arc-dpa predictions, but the number of interstitials is reduced by about one order of magnitude compared to vacancies, at 5 keV. According to the radiation resistance found for FeCu CSNP in our simulations, this class of nanomaterial could be suitable for developing new radiation-resistant coatings, nanostructured components, and shields for use in extreme environments, for instance, in nuclear energy and astrophysical applications.es
dc.description.sponsorshipWe thank D. Schwen and X. Bai for kindly providing their interatomic potential tables. DT acknowledges support from DIUM. DT, OD, and EMB thank the support from SIIP-UNCUYO 06/M008-T1 and PICTO-UM-2019-00048. We used Serafin Cluster (CCAD-UNC) and Toko (UNCuyo) clusters, which are part of SNCAD-MinCyT, Argentina. RP acknowledges a scientific fund from Sistema Nacional de Investigacion de Panama (SNI) and SENACYT Projects: FID-2016-275 and EIE18-16. HPC-Cluster Iberogun Group gratefully acknowledges the support of NVIDIA Corporation with the donation of the Titan Xp GPU used for this research. FV a RIG thank Fondo Nacional de Investigaciones Cientificas y Tecnologicas (FONDECYT, Chile) under grants 1190662, 11190484, and 11180557. This research was partially supported by the supercomputing infrastructure of the NLHPC (ECM-02) . SEB, FV, RIG and JRN acknowledge the support from the Basal Program for Centers of Excellence, Grant AFB220001 CEDENNA, CONICYT. SEB and JRN acknowledge the support of VRIDEI POSTDOC-DICYT under project 042231BR-Postdoc. RCP acknowledges support from project PICT 2019-02912 ANPCyT.es
dc.format.extent13 p., PDFes
dc.language.isoen_USes
dc.publisherELSEVIERes
dc.rightsAttribution-NonCommercial-NoDerivs 3.0 Chilees
dc.titleProbing radiation resistance in simulated metallic core-shell nanoparticleses
dc.typeArtículo o Paperes
umayor.indizadorCOTes
umayor.indexadoWeb of Sciencees
umayor.indexadoScopuses
dc.identifier.doi10.1016/j.commatsci.2023.112304
umayor.indicadores.wos-(cuartil)Q1
umayor.indicadores.scopus-(scimago-sjr)SJR 0,77
umayor.indicadores.scopus-(scimago-sjr)SCIMAGO/ INDICE H: 135


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