A model for local generation of nanoparticles in photoinduced nanocomposites by the focused laser light

A model for local generation of nanoparticles in photoinduced nanocomposites by the focused laser light

•Long-time rate of elementary species generation is limited by the precursor diffusion.•Shell-shaped structures can be obtained with conventional non-vortex laser beam.•Precipitation can be localized due to the trapping effect of the growing nuclei.•Critical initial concentration of the precursor is...

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Bibliographic Details
Published in:Applied surface science Vol. 475; pp. 1010 - 1020
Main Authors: Pikulin, Alexander, Smirnov, Anton A., Bityurin, Nikita
Format: Journal Article
Language:English
Published: Elsevier B.V 01-05-2019
Subjects:
Diffusion
Laser nanopatterning
Modeling
Nanoparticles
Phase transitions
Photoinduced nanocomposites
Nanoparticles
Photoinduced nanocomposites
Laser nanopatterning
Diffusion
Modeling
Phase transitions
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Summary:•Long-time rate of elementary species generation is limited by the precursor diffusion.•Shell-shaped structures can be obtained with conventional non-vortex laser beam.•Precipitation can be localized due to the trapping effect of the growing nuclei.•Critical initial concentration of the precursor is required for the trapping effect. Metal or semiconductor nanoparticles (NPs) can be instantly generated in polymers under the irradiation by light, thus converting them into the photoinduced nanocomposites. The light causes the photodestruction of the precursor molecules dissolved in the polymer matrix. As a result, some kind of elementary species (such as atoms of metal) are released and then precipitate into the NPs right within the bulk of the material. This paper considers theoretically the kinetics of the localized NP generation under the prolonged irradiation by the focused continuous-wave or pulsed laser light. It is shown that the maximal rate at which the elementary species can be generated by the laser beam is determined by the balance between the depletion rate of the precursor within the irradiated spot and its diffusion flux from the surrounding volume. The optimal beam power that yields the maximal species generation rate at the focus is calculated. At that and smaller beam power, the maximum material modification is located at the maximum of the laser intensity. With the higher beam power, the material modification can be performed within the hollow volume, leaving the focus untouched. The possibility of the local generation of NPs is studied within the framework of the simplest homogenous nucleation model. The locally generated elementary species tend to leave the irradiated zone due to the diffusion. However, if the initial precursor concentration is high enough, the growing NPs act as traps for elementary species thus impeding this delocalization effect.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2018.12.276