Band gap of nanometer thick Si/SiO<sub>2</sub> quantum wells: theory versus experiment

D. J. Lockwood

doi:10.1117/12.804577

12 August 2008 Band gap of nanometer thick Si/SiO₂ quantum wells: theory versus experiment

D. J. Lockwood

Proceedings Volume 7099, Photonics North 2008; 70991F (2008) https://doi.org/10.1117/12.804577
Event: Photonics North 2008, 2008, Montréal, Canada

Abstract

In opto-electronics and photonics, the severe disadvantage of an indirect band gap has limited the application of elemental silicon. Amongst a number of diverse approaches to engineering efficient light emission in silicon nanostructures, one system that has received considerable attention has been Si/SiO₂ quantum wells. Engineering such structures has not been easy, because to observe the desired quantum confinement effects, the quantum well thickness has to be less than 5 nm. Nevertheless, such nanometer thick structures have now been produced by a variety of techniques. The SiO₂ layers are amorphous, but the silicon layers can range from amorphous through nanocrystalline to single-crystal form. The fundamental band gap of the quantum wells has been measured primarily by optical techniques and strong confinement effects have been observed. A number of theories based primarily on ab initio approaches have been developed to explain these results with varying degrees of success. In this review, a detailed comparison is made between theoretical and experimental determinations of the band gap in Si/SiO₂ quantum wells.

Citation Download Citation

D. J. Lockwood "Band gap of nanometer thick Si/SiO₂ quantum wells: theory versus experiment", Proc. SPIE 7099, Photonics North 2008, 70991F (12 August 2008); https://doi.org/10.1117/12.804577

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