Silicon Nanowire Polytypes: Identification by Raman Spectroscopy, Generation Mechanism, and Misfit Strain in Homostructures

López, Francisco J.; Givan, Uri; Connell, Justin G.; Lauhon, Lincoln J.

doi:10.1021/nn2031337

Cited by 67 publications

(82 citation statements)

References 65 publications

(112 reference statements)

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“…We are aware that this approach could result in overestimation of the doping concentration. In addition, the attribution of the optical phonons peak wavenumber is not straightforward because the wavenumber positions of the optical phonons peaks of wurtzite silicon are still an open issue1326272829.…”

Section: Resultsmentioning

confidence: 99%

Visible and Infra-red Light Emission in Boron-Doped Wurtzite Silicon Nanowires

Fabbri

Rotunno

Lazzarini

et al. 2014

Sci Rep

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Silicon, the mainstay semiconductor in microelectronic circuitry, is considered unsuitable for optoelectronic applications owing to its indirect electronic band gap, which limits its efficiency as a light emitter. Here we show the light emission properties of boron-doped wurtzite silicon nanowires measured by cathodoluminescence spectroscopy at room temperature. A visible emission, peaked above 1.5 eV, and a near infra-red emission at 0.8 eV correlate respectively to the direct transition at the Γ point and to the indirect band-gap of wurtzite silicon. We find additional intense emissions due to boron intra-gap states in the short wavelength infra-red range. We present the evolution of the light emission properties as function of the boron doping concentration and the growth temperature.

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Section: Resultsmentioning

confidence: 99%

Visible and Infra-red Light Emission in Boron-Doped Wurtzite Silicon Nanowires

Fabbri

Rotunno

Lazzarini

et al. 2014

Sci Rep

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“…Wurtzite Si structure was also identified in CVD Si nanowires 16,35,36 . Recently, uniform wurtzite silicon shells were epitaxially grown on hexagonal GaP nanowire cores 37 .…”

Section: Based On Above Observation That No Infrared Emission Was Detmentioning

confidence: 93%

Broadband infrared photoluminescence in silicon nanowires with high density stacking faults

Liu

et al. 2015

Nanoscale

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Making silicon an efficient light-emitting material is an important goal of silicon photonics. Here we report the observation of broadband sub-bandgap photoluminescence in silicon nanowires with a high density of stacking faults. The photoluminescence becomes stronger and exhibits a blue shift under higher laser powers. The super-linear dependence on excitation intensity indicates a strong competition between radiative and defect-related non-radiative channels, and the spectral blue shift is ascribed to the band filling effect in the heterostructures of wurtzite silicon and cubic silicon created by stacking faults.

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“…Raman spectroscopy reports on the phonon spectrum of a material, which constitutes a fingerprint of the crystal structure. This technique has often been used in the characterization of polytypism in III-V nanostructures [69][70][71]. It possesses the advantage that it allows a fast non-destructive measurement and therefore the realization of a high number of measurements and statistics on a same sample.…”

Section: General Structural Characterization By Raman Spectroscopymentioning

confidence: 99%

Growth mechanisms and process window for InAs V-shaped nanoscale membranes on Si[001]

Russo-Averchi¹,

Dalmau-Mallorquí²,

Canales-Mundet³

et al. 2013

Nanotechnology

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Organized growth of high aspect-ratio nanostructures such as membranes is interesting for opto-electronic and energy harvesting applications. Recently, we reported a new form of InAs nano-membranes grown on Si substrates with enhanced light scattering properties. In this paper we study how to tune the morphology of the membranes by changing the growth conditions. We examine the role of the V/III ratio, substrate temperature, mask opening size and inter-hole distances in determining the size and shape of the structures. Our results show that the nano-membranes form by a combination of the growth mechanisms of nanowires and the Stranski-Krastanov type of quantum dots: in analogy with nanowires, the length of the membranes strongly depends on the growth temperature and the V/III ratio; the inter-hole distance of the sample determines two different growth regimes: competitive growth for small distances and an independent regime for larger distances. Conversely, and similarly to quantum dots, the width of the nano-membranes increases with the growth temperature and does not exhibit dependence on the V/III ratio. These results constitute an important step towards achieving rational design of high aspect-ratio nanostructures.

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Silicon Nanowire Polytypes: Identification by Raman Spectroscopy, Generation Mechanism, and Misfit Strain in Homostructures

Cited by 67 publications

References 65 publications

Visible and Infra-red Light Emission in Boron-Doped Wurtzite Silicon Nanowires

Visible and Infra-red Light Emission in Boron-Doped Wurtzite Silicon Nanowires

Broadband infrared photoluminescence in silicon nanowires with high density stacking faults

Growth mechanisms and process window for InAs V-shaped nanoscale membranes on Si[001]

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