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dc.contributorUniv Mayor, Fac Ciencias, Ctr Nanotecnol Aplicada, Chilees
dc.contributor.authorMillan, Emmanuel N.
dc.contributor.authorPlanes, María Belén
dc.contributor.authorUrbassek, Herbert M.
dc.contributor.authorBringa, Eduardo M. [Univ Mayor, Fac Ciencias, Ctr Nanotecnol Aplicada, Chile]
dc.date.accessioned2024-03-21T19:23:43Z
dc.date.available2024-03-21T19:23:43Z
dc.date.issued2023-03-29
dc.identifier.citationMillán, E. N., Planes, M. B., Urbassek, H. M., & Bringa, E. M. (2023). A Monte Carlo code for the collisional evolution of porous aggregates (CPA). Astronomy & Astrophysics, 672, A50.es
dc.identifier.issn0004-6361
dc.identifier.issneISSN 1432-0746
dc.identifier.otherWOS:000961211500008
dc.identifier.otherSCOPUS: SCOPUS_ID:85153083283
dc.identifier.urihttps://repositorio.umayor.cl/xmlui/handle/sibum/9492
dc.identifier.urihttps://www.aanda.org/articles/aa/pdf/2023/04/aa43069-22.pdf
dc.identifier.urihttps://doi.org/10.1051/0004-6361/202243069
dc.description.abstractContext. The collisional evolution of submillimeter-sized porous dust aggregates is important in many astrophysical fields.Aims. We have developed a Monte Carlo code to study the processes of collision between mass-asymmetric, spherical, micron-sized porous silica aggregates that belong to a dust population.Methods. The Collision of Porous Aggregates (CPA) code simulates collision chains in a population of dust aggregates that have different sizes, masses, and porosities. We start from an initial distribution of granular aggregate sizes and assume some collision velocity distribution. In particular, for this study we used a random size distribution and a Maxwell-Boltzmann velocity distribution. A set of successive random collisions between pairs of aggregates form a single collision chain. The mass ratio, filling factor, and impact velocity influence the outcome of the collision between two aggregates. We averaged hundreds of thousands of independent collision chains to obtain the final, average distributions of aggregates.Results. We generated and studied four final distributions (F), for size (n), radius (R), porosity, and mass-porosity distributions, for a relatively low number of collisions. In general, there is a profuse generation of monomers and small clusters, with a distribution F (R) proportional to R-6 for small aggregates. Collisional growth of a few very large clusters is also observed. Collisions lead to a significant compaction of the dust population, as expected.Conclusions. The CPA code models the collisional evolution of a dust population and incorporates some novel features, such as the inclusion of mass-asymmetric aggregates (covering a wide range of aggregate radii), inter-granular friction, and the influence of porosity.es
dc.description.sponsorshipB.P., E.M., and E.M.B. acknowledge support from ANPCyT PICTO-UUMM-2019-00048 and SIIP 06/M008-T1. This work used the Toko Cluster from FCEN, UNCuyo, which is part of the SNCAD, MinCyT, Argentina.es
dc.format.extent18 p., PDFes
dc.language.isoen_USes
dc.publisherEDP SCIENCES S Aes
dc.rightsAttribution-NonCommercial-NoDerivs 3.0 Chilees
dc.titleA Monte Carlo code for the collisional evolution of porous aggregates (CPA)es
dc.typeArtículo o Paperes
umayor.indizadorCOTes
umayor.indexadoWeb of Sciencees
umayor.indexadoScopuses
dc.identifier.doi10.1051/0004-6361/202243069
umayor.indicadores.wos-(cuartil)Q1
umayor.indicadores.scopus-(scimago-sjr)SJR 2
umayor.indicadores.scopus-(scimago-sjr)SCIMAGO/ INDICE H: 320


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