In the synthesis of nanostructures by pulsed laser deposition (PLD), a crucial role is played by the environmental deposition pressure and the substrate temperature. Due to the high temperature of nanoparticles (NPs) at landing, other factors may determine the structure of the resulting aggregates. Here, Au and TiO2nanostructures are obtained by non-thermal fs-PLD in ambient conditions. On Si(100), only TiO2 NPs form fractals with areas up to ~ 1 x10^6 nm^2, while on quartz Au NPs also form fractals with areas up to ~ 5 x10^3 nm^2, a much smaller size with respect to the TiO2 case. The aggregation is described by a simple diffusive model, taking into account isotropic diffusion of the NPs, allowing quantitative simulations of the NPs and fractal area. The results highlight the key role of substrate thermal conductivity in determining the formation of fractals. [Figure not available: see fulltext.].
Cavaliere, E., Benetti, G., Celardo, G. L., Archetti, D., Pingue, P., Ferrini, G., Gavioli, L., Aggregation and fractal formation of Au and TiO2nanostructures obtained by fs-pulsed laser deposition: experiment and simulation, <<JOURNAL OF NANOPARTICLE RESEARCH>>, 2017; (19): 311-317. [doi:10.1007/s11051-017-4009-1] [http://hdl.handle.net/10807/110183]
Aggregation and fractal formation of Au and TiO2nanostructures obtained by fs-pulsed laser deposition: experiment and simulation
Cavaliere, Emanuele;Benetti, Giulio;Ferrini, Gabriele;Gavioli, Luca
2017
Abstract
In the synthesis of nanostructures by pulsed laser deposition (PLD), a crucial role is played by the environmental deposition pressure and the substrate temperature. Due to the high temperature of nanoparticles (NPs) at landing, other factors may determine the structure of the resulting aggregates. Here, Au and TiO2nanostructures are obtained by non-thermal fs-PLD in ambient conditions. On Si(100), only TiO2 NPs form fractals with areas up to ~ 1 x10^6 nm^2, while on quartz Au NPs also form fractals with areas up to ~ 5 x10^3 nm^2, a much smaller size with respect to the TiO2 case. The aggregation is described by a simple diffusive model, taking into account isotropic diffusion of the NPs, allowing quantitative simulations of the NPs and fractal area. The results highlight the key role of substrate thermal conductivity in determining the formation of fractals. [Figure not available: see fulltext.].
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