From Solid-State Dewetting of Ultrathin, Compressively Strained Silicon–Germanium-on-Insulator Films to Mastering the Stoichiometry of Si1–x Ge x Nanocrystals

The mastering of material composition at the nanoscale is of prime importance for many applications. In this context, we developed a simply implementable and fast germanium enrichment method allowing the control of the germanium fraction within silicon–germanium nanocrystals. In our process, the tun...

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Bibliographic Details
Published in:Journal of physical chemistry. C 2016-04, Vol.120 (13), p.7412-7420
Main Authors: Almadori, Yann, Borowik, Łukasz, Chevalier, Nicolas, Hourani, Wael, Glowacki, Frédérique, Barbé, Jean-Charles
Format: Article
Language:English
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Summary:The mastering of material composition at the nanoscale is of prime importance for many applications. In this context, we developed a simply implementable and fast germanium enrichment method allowing the control of the germanium fraction within silicon–germanium nanocrystals. In our process, the tuning of the stoichiometry is achieved in the background of thermally induced solid-state dewetting, followed by a solid–solid interfacial reaction step between nanocrystals issued from dewetting and the silicon dioxide substrate. At first, we show by scanning transmission electron microscopy and scanning Auger microscopy that homogeneous silicon–germanium nanocrystals are successfully formed by means of solid-state dewetting of silicon–germanium-on-insulator ultrathin films. Then, we demonstrate that an interfacial reaction between the silicon–germanium of the nanocrystals and the silicon dioxide of the substrate can be thermally induced under ultrahigh vacuum conditions. The reaction, entailing almost exclusively silicon, permits us to modify the germanium fraction within silicon–germanium nanocrystals by controlling its advancement. Finally, we highlight the possibility to control the stoichiometry of silicon–germanium nanostructures simply by using thermal effects.
ISSN:1932-7447
1932-7455
DOI:10.1021/acs.jpcc.6b01093