Solid-State Dewetting of Gold Aggregates/Islands on TiO<sub>2</sub> Nanorod Structures Grown by Oblique Angle Deposition

Liu, Shizhao; Plawsky, Joel L.

doi:10.1021/acs.langmuir.7b03259

Cited by 5 publications

(1 citation statement)

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“…At this point, we want to note that there exist phase-field studies pertaining to the phenomena of solid-state dewetting in nanowires [53,54,17]. Different phenomena like the formation of nanoparticles through solid-state dewetting of a thin-film on a substrate [55], stress effects on solid-state dewetting of thin-films [56], solid-state dewetting of Au aggregates on titanium oxide nanorods [57], and effect of surface energy anisotropy on Rayleigh-like solid-state dewetting [17] have been studied in the past. However, unlike these models which include the substrate on which dewetting takes place, in our model, the wires are free-standing.…”

Section: Introductionmentioning

confidence: 99%

Phase-field study of surface diffusion enhanced break-ups of nanowire junctions

Roy,

Gururajan

2021

Preprint

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Using a phase-field model which incorporates enhanced diffusion at the nanowire surfaces, we study the effect of different parameters on the stability of intersecting nanowires. Our study shows that at the intersection of nanowires, sintering (curvature driven material flow) leads to the formation of junctions. These junctions act the initiators of nanowire break-up. The subsequent breakups take place due to Rayleigh instability at the arms away from these junctions. Finally, at long time scales, the fragments coarsen due to the differences in sizes. The radii of the nanowires that form the junction, the difference in size of the intersecting nanowires and the angle of intersection play a dominant role in determining the kinetics of break-up while the density of intersections has little or no effect on the kinetics. The surface energy anisotropy makes the nanowires with favourable interfaces stable. However, even in the case of nanowires with anisotropic interfacial energy, the fragmentation behaviour is qualitatively the same in terms of formation of junctions and the first break-up at the junction. Finally, we rationalise our results using maps of Gaussian curvatures (and, hence chemical potentials).

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