Ultra-small photoluminescent silicon-carbide nanocrystals by atmospheric-pressure plasmas

Sadegh Askari; Atta Ul Haq; Manuel Macias-Montero; Igor Levchenko; Fengjiao Yu; Wuzong Zhou; Kostya Ostrikov; Paul Maguire; Vladimir Svrcek; Davide Mariotti

doi:10.1039/c6nr03702j

Ultra-small photoluminescent silicon-carbide nanocrystals by atmospheric-pressure plasmas

Sadegh Askari, Atta Ul Haq, Manuel Macias-Montero, Igor Levchenko, Fengjiao Yu, Wuzong Zhou, Kostya Ostrikov, Paul Maguire, Vladimir Svrcek, Davide Mariotti^*

^*Corresponding author for this work

Design, Manufacturing And Engineering Management

Research output: Contribution to journal › Article › peer-review

51 Citations (Scopus)

Abstract

Highly size-controllable synthesis of free-standing perfectly crystalline silicon carbide nanocrystals has been achieved for the first time through a plasma-based bottom-up process. This low-cost, scalable, ligand-free atmospheric pressure technique allows fabrication of ultra-small (down to 1.5 nm) nanocrystals with very low level of surface contamination, leading to fundamental insights into optical properties of the nanocrystals. This is also confirmed by their exceptional photoluminescence emission yield enhanced by more than 5 times by reducing the nanocrystals sizes in the range of 1-5 nm, which is attributed to quantum confinement in ultra-small nanocrystals. This method is potentially scalable and readily extendable to a wide range of other classes of materials. Moreover, this ligand-free process can produce colloidal nanocrystals by direct deposition into liquid, onto biological materials or onto the substrate of choice to form nanocrystal films. Our simple but efficient approach based on non-equilibrium plasma environment is a response to the need of most efficient bottom-up processes in nanosynthesis and nanotechnology.

Original language	English
Pages (from-to)	17141-17149
Number of pages	9
Journal	Nanoscale
Volume	8
Issue number	39
Early online date	23 Sept 2016
DOIs	https://doi.org/10.1039/c6nr03702j
Publication status	Published - 21 Oct 2016

Funding

This work was supported by the Royal Society International Exchange Scheme (IE120884), the Leverhulme International Network (IN-2012-136), EPSRC (EP/K022237/1 and EP/M024938/1) and EU-FP7 (award n.606889). S. A. and A. U. H. thank the financial support of the University of Ulster Vice-Chancellor Studentship and EU-funded ITN, respectively (award n.606889). IL and KO acknowledge financial support from CSIRO and Australian Research Council. I. L. acknowledges support from the School of Chemistry, Physics and Mechanical Engineering, Science and Engineering Faculty, Queensland University of Technology

Keywords

atmospheric pressure
biological materials
films
ligands
optical properties

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Cite this

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title = "Ultra-small photoluminescent silicon-carbide nanocrystals by atmospheric-pressure plasmas",

abstract = "Highly size-controllable synthesis of free-standing perfectly crystalline silicon carbide nanocrystals has been achieved for the first time through a plasma-based bottom-up process. This low-cost, scalable, ligand-free atmospheric pressure technique allows fabrication of ultra-small (down to 1.5 nm) nanocrystals with very low level of surface contamination, leading to fundamental insights into optical properties of the nanocrystals. This is also confirmed by their exceptional photoluminescence emission yield enhanced by more than 5 times by reducing the nanocrystals sizes in the range of 1-5 nm, which is attributed to quantum confinement in ultra-small nanocrystals. This method is potentially scalable and readily extendable to a wide range of other classes of materials. Moreover, this ligand-free process can produce colloidal nanocrystals by direct deposition into liquid, onto biological materials or onto the substrate of choice to form nanocrystal films. Our simple but efficient approach based on non-equilibrium plasma environment is a response to the need of most efficient bottom-up processes in nanosynthesis and nanotechnology.",

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AU - Askari, Sadegh

AU - Ul Haq, Atta

AU - Macias-Montero, Manuel

AU - Levchenko, Igor

AU - Yu, Fengjiao

AU - Zhou, Wuzong

AU - Ostrikov, Kostya

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AU - Svrcek, Vladimir

AU - Mariotti, Davide

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AB - Highly size-controllable synthesis of free-standing perfectly crystalline silicon carbide nanocrystals has been achieved for the first time through a plasma-based bottom-up process. This low-cost, scalable, ligand-free atmospheric pressure technique allows fabrication of ultra-small (down to 1.5 nm) nanocrystals with very low level of surface contamination, leading to fundamental insights into optical properties of the nanocrystals. This is also confirmed by their exceptional photoluminescence emission yield enhanced by more than 5 times by reducing the nanocrystals sizes in the range of 1-5 nm, which is attributed to quantum confinement in ultra-small nanocrystals. This method is potentially scalable and readily extendable to a wide range of other classes of materials. Moreover, this ligand-free process can produce colloidal nanocrystals by direct deposition into liquid, onto biological materials or onto the substrate of choice to form nanocrystal films. Our simple but efficient approach based on non-equilibrium plasma environment is a response to the need of most efficient bottom-up processes in nanosynthesis and nanotechnology.

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Ultra-small photoluminescent silicon-carbide nanocrystals by atmospheric-pressure plasmas

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Keywords

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