Surface-engineered silicon nanocrystals

Davide Mariotti; Somak Mitra; Vladimir Švrček

doi:10.1039/c2nr33170e

Surface-engineered silicon nanocrystals

Davide Mariotti^*, Somak Mitra, Vladimir Švrček

^*Corresponding author for this work

Design, Manufacturing And Engineering Management

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

67 Citations (Scopus)

Abstract

Quantum confined silicon nanocrystals (Si-ncs) exhibit intriguing properties due to silicon's indirect bandgap and their highly reactive surfaces. In particular the interplay of quantum confinement with surface effects reveals a complex scenario, which can complicate the interpretation of Si-nc properties and prediction of their corresponding behaviour. At the same time, the complexity and interplay of the different mechanisms in Si-ncs offer great opportunities with characteristics that may not be achievable with other nano-systems. In this context, a variety of carefully surface-engineered Si-ncs are highly desirable both for improving our understanding of Si-nc photo-physics and for their successful integration in application devices. Here we firstly highlight a selection of theoretical efforts and experimental surface engineering approaches and secondly we focus on recent surface engineering results that have utilized novel plasma-liquid interactions.

Original language	English
Pages (from-to)	1385-1398
Number of pages	14
Journal	Nanoscale
Volume	5
Issue number	4
Early online date	11 Dec 2012
DOIs	https://doi.org/10.1039/c2nr33170e
Publication status	Published - 21 Feb 2013

Keywords

computer simulation
crystallization
macromolecular substances
materials testing

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10.1039/c2nr33170e

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AU - Mariotti, Davide

AU - Mitra, Somak

AU - Švrček, Vladimir

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N2 - Quantum confined silicon nanocrystals (Si-ncs) exhibit intriguing properties due to silicon's indirect bandgap and their highly reactive surfaces. In particular the interplay of quantum confinement with surface effects reveals a complex scenario, which can complicate the interpretation of Si-nc properties and prediction of their corresponding behaviour. At the same time, the complexity and interplay of the different mechanisms in Si-ncs offer great opportunities with characteristics that may not be achievable with other nano-systems. In this context, a variety of carefully surface-engineered Si-ncs are highly desirable both for improving our understanding of Si-nc photo-physics and for their successful integration in application devices. Here we firstly highlight a selection of theoretical efforts and experimental surface engineering approaches and secondly we focus on recent surface engineering results that have utilized novel plasma-liquid interactions.

AB - Quantum confined silicon nanocrystals (Si-ncs) exhibit intriguing properties due to silicon's indirect bandgap and their highly reactive surfaces. In particular the interplay of quantum confinement with surface effects reveals a complex scenario, which can complicate the interpretation of Si-nc properties and prediction of their corresponding behaviour. At the same time, the complexity and interplay of the different mechanisms in Si-ncs offer great opportunities with characteristics that may not be achievable with other nano-systems. In this context, a variety of carefully surface-engineered Si-ncs are highly desirable both for improving our understanding of Si-nc photo-physics and for their successful integration in application devices. Here we firstly highlight a selection of theoretical efforts and experimental surface engineering approaches and secondly we focus on recent surface engineering results that have utilized novel plasma-liquid interactions.

KW - computer simulation

KW - crystallization

KW - macromolecular substances

KW - materials testing

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DO - 10.1039/c2nr33170e

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EP - 1398

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Surface-engineered silicon nanocrystals

Abstract

Keywords

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