Laser-induced deposition of metal and hybrid metal-carbon nanostructures

Research outputpeer-review

Abstract

This chapter considers the problem of laser-matter interaction in the sense of laser-initiated chemical processes and subsequent formation of solid nanostructured materials. The main attention is focused to the effects originated as a result of laser impact onto heterogenic systems such as ‘solid-liquid’ interfaces, and in particular for the case when the chemical activity of the heterogenic system as a whole is mainly determined by the laser-induced effects in liquid phase. That is why all the issues connected to the laser ablation phenomena are out of the chapter scope. Heterogenic systems (substrate-solution interfaces) are extremely curious targets for the laser irradiation because of a much wider diversity of chemical processes as compared with homogeneous systems (solutions or solids). Another peculiarity of the selected system is the possibility of the chemical activity tuning by selecting either photochemical or thermochemical mode of laser exposure. This laser-induced approach proved to be efficient for one-step formation of the metal and hybrid metal-carbon nanostructures on the surface of the various kinds of substrates. The peculiarities of the laser-induced processes for the case of different solutions (electrolyte solutions or solutions of organometallic complexes) and different regimes of laser irradiation (thermal or photo-induced) are considered; as well as the possibility of the directed control of the composition of the deposited nanostructures is presented. It is important to note that the essential advantage of the laser-induced processes under discussion is the spatial control of the deposited structures that are formed in the laser-affected area of the substrate. The last circumstance together with well controlled composition and morphology ensure diverse functional properties of the laser-deposited nanostructures.

Original languageEnglish
Title of host publicationSpringer Series in Chemical Physics
PublisherSpringer
Pages387-403
Number of pages17
DOIs
Publication statusPublished - 1 Jan 2019

Publication series

NameSpringer Series in Chemical Physics
Volume119
ISSN (Print)0172-6218

Fingerprint

Nanostructures
Carbon
Metals
Lasers
carbon
metals
lasers
Laser beam effects
Substrates
Chemical lasers
Liquids
Organometallics
Laser ablation
Laser modes
Chemical analysis
Nanostructured materials
Electrolytes
irradiation
liquid-solid interfaces
Tuning

Scopus subject areas

  • Physical and Theoretical Chemistry

Cite this

Manshina, A. (2019). Laser-induced deposition of metal and hybrid metal-carbon nanostructures. In Springer Series in Chemical Physics (pp. 387-403). (Springer Series in Chemical Physics; Vol. 119). Springer. https://doi.org/10.1007/978-3-030-05974-3_20
Manshina, Alina. / Laser-induced deposition of metal and hybrid metal-carbon nanostructures. Springer Series in Chemical Physics. Springer, 2019. pp. 387-403 (Springer Series in Chemical Physics).
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Manshina, A 2019, Laser-induced deposition of metal and hybrid metal-carbon nanostructures. in Springer Series in Chemical Physics. Springer Series in Chemical Physics, vol. 119, Springer, pp. 387-403. https://doi.org/10.1007/978-3-030-05974-3_20

Laser-induced deposition of metal and hybrid metal-carbon nanostructures. / Manshina, Alina.

Springer Series in Chemical Physics. Springer, 2019. p. 387-403 (Springer Series in Chemical Physics; Vol. 119).

Research outputpeer-review

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Manshina A. Laser-induced deposition of metal and hybrid metal-carbon nanostructures. In Springer Series in Chemical Physics. Springer. 2019. p. 387-403. (Springer Series in Chemical Physics). https://doi.org/10.1007/978-3-030-05974-3_20