Band structure of germanium carbides for direct bandgap silicon photonics

Research output: Journal Publications and Reviews (RGC: 21, 22, 62)21_Publication in refereed journalpeer-review

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Author(s)

  • C. A. Stephenson
  • W. A. O'Brien
  • M. W. Penninger
  • W. F. Schneider
  • M. Gillett-Kunnath
  • J. Zajicek
  • R. Kudrawiec
  • R. A. Stillwell
  • M. A. Wistey

Detail(s)

Original languageEnglish
Article number53102
Journal / PublicationJournal of Applied Physics
Volume120
Issue number5
Publication statusPublished - 7 Aug 2016

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Publisher's Copyright Statement
  • This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in C. A. Stephenson, W. A. O'Brien, M. W. Penninger, W. F. Schneider, M. Gillett-Kunnath, J. Zajicek, K. M. Yu, R. Kudrawiec, R. A. Stillwell, and M. A. Wistey , "Band structure of germanium carbides for direct bandgap silicon photonics", Journal of Applied Physics 120, 053102 (2016) and may be found at https://doi.org/10.1063/1.4959255.
Link to Scopus https://www.scopus.com/record/display.uri?eid=2-s2.0-84981223991&origin=recordpage
Permanent Link https://scholars.cityu.edu.hk/en/publications/publication(a627bc9c-fbf8-4551-9d20-44ce79067b5e).html

Abstract

Compact optical interconnects require efficient lasers and modulators compatible with silicon. Ab initio modeling of Ge1-xCx (x = 0.78%) using density functional theory with HSE06 hybrid functionals predicts a splitting of the conduction band at Γ and a strongly direct bandgap, consistent with band anticrossing. Photoreflectance of Ge0.998C0.002 shows a bandgap reduction supporting these results. Growth of Ge0.998C0.002 using tetrakis(germyl)methane as the C source shows no signs of C-C bonds, C clusters, or extended defects, suggesting highly substitutional incorporation of C. Optical gain and modulation are predicted to rival III-V materials due to a larger electron population in the direct valley, reduced intervalley scattering, suppressed Auger recombination, and increased overlap integral for a stronger fundamental optical transition.

Research Area(s)

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Publication fingerprints text

100
Energy gap Engineering & Materials S...
52
Optical gain Engineering & Materials S...
52
Silicon Engineering & Materials S...
49
Optical transitions Engineering & Materials S...
48
Optical interconnec... Engineering & Materials S...
47
Light modulation Engineering & Materials S...
41
Conduction bands Engineering & Materials S...
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Germanium Engineering & Materials S...
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Band structure Engineering & Materials S...
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Photonics Engineering & Materials S...
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Citation Format(s)

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Band structure of germanium carbides for direct bandgap silicon photonics. / Stephenson, C. A.; O'Brien, W. A.; Penninger, M. W. et al.

In: Journal of Applied Physics, Vol. 120, No. 5, 53102, 07.08.2016.

Research output: Journal Publications and Reviews (RGC: 21, 22, 62)21_Publication in refereed journalpeer-review

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