Cluster-doping in silicon nanocrystals

Creating tin-alloyed silicon nanocrystals with tailored bandgap values is a significant challenge, primarily because a substantial concentration of tin is essential to observe useful changes in the electronic structure. However, high concentration of Sn leads to instability of the silicon-tin nanocr...

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Bibliographic Details
Published in:Nanoscale horizons 2024-10, Vol.9 (11), p.242-25
Main Authors: Haq, Atta ul, Buerkle, Marius, Alessi, Bruno, Svrcek, Vladimir, Maguire, Paul, Mariotti, Davide
Format: Article
Language:English
Subjects:
Alloying
Clusters
Doping
Electronic structure
Energy gap
First principles
Microplasmas
Nanocrystals
Pressure dependence
Silicon
Structural stability
Tin
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Summary:Creating tin-alloyed silicon nanocrystals with tailored bandgap values is a significant challenge, primarily because a substantial concentration of tin is essential to observe useful changes in the electronic structure. However, high concentration of Sn leads to instability of the silicon-tin nanocrystals. This work introduces a completely new approach to doping and the modification of the electronic structure of nanoparticles by incorporating few-atom clusters in nanocrystals, deviating from isolated atom doping or attempting alloying. This approach is exemplified via a combined theoretical and experimental study on tin (Sn) 'cluster-doping' of silicon (Si) nanocrystals, motivated by the opportunities offered by the Si-Sn system with tailored band energy. First-principles modelling predicts two noteworthy outcomes: a considerably smaller bandgap of these nanocrystals even with a modest concentration of tin compared to an equivalent-sized pure silicon nanocrystal and an unexpected decrease in the bandgap of nanocrystals as the diameter of nanocrystals increases, contrary to the typical quantum confined behaviour. Experimental verification using atmospheric pressure microplasma synthesis confirms the stability of these nanocrystals under ambient conditions. The plasma-synthesised nanocrystals exhibited the predicted atypical size-dependent behaviour of the bandgap, which ranged from 1.6 eV for 1.4 nm mean diameter particles to 2.4 eV for 2.2 nm mean diameter particles. Sn-cluster doping of Si nanocrystals represents a new approach to property tuning, which results in a significant bandgap reduction and an atypical size-dependent behaviour, as confirmed by both experimental and theoretical studies.
ISSN:2055-6756
2055-6764
2055-6764
DOI:10.1039/d4nh00235k