Artículo
Why nanoprojectiles work differently than macroimpactors: The role of plastic flow
Anders, Christian; Bringa, Eduardo Marcial
; Ziegenhain, Gerolf; Graham, Giles A.; Hansen, J. Freddy; Park, Nigel; Teslich, Nick E.; Urbassek, Herbert M.
Fecha de publicación:
01/2012
Editorial:
American Physical Society
Revista:
Physical Review Letters
ISSN:
0031-9007
Idioma:
Inglés
Tipo de recurso:
Artículo publicado
Clasificación temática:
Resumen
Atomistic simulation data on crater formation due to the hypervelocity impact of nanoprojectiles of up to 55 nm diameter and with targets containing up to 10^10 atoms are compared to available experimental data on micron-, mm-, and cm-sized projectiles. We show that previous scaling laws do not hold in the nanoregime and outline the reasons: within our simulations we observe that the cratering mechanism changes, going from the smallest to the largest simulated scales, from an evaporative regime to a regime where melt and plastic flow dominate, as is expected in larger microscale experiments. The importance of the strain-rate dependence of strength and of dislocation production and motion are discussed.
Palabras clave:
craters
,
molecular dynamics
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Articulos(CCT - MENDOZA)
Articulos de CTRO.CIENTIFICO TECNOL.CONICET - MENDOZA
Articulos de CTRO.CIENTIFICO TECNOL.CONICET - MENDOZA
Citación
Anders, Christian; Bringa, Eduardo Marcial; Ziegenhain, Gerolf; Graham, Giles A.; Hansen, J. Freddy; et al.; Why nanoprojectiles work differently than macroimpactors: The role of plastic flow; American Physical Society; Physical Review Letters; 108; 2; 1-2012; 27601-27605
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