A precise optical determination of nanoscale diameters of semiconductor nanowires

Brönstrup, Gerald; Leiterer, Christian; Jahr, Norbert; Gutsche, Christoph; Lysov, Andrey; Regolin, I.; Prost, W.; Tegude, F.‐J.; Fritzsche, Wolfgang; Christiansen, Silke

doi:10.1088/0957-4484/22/38/385201

Cited by 32 publications

(37 citation statements)

References 25 publications

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“…Indeed, it has been shown that even a small tapering of semiconductor NWs affects the scattering resonances. 23,32 In the present case the tapering of the NW is about 1 magnitude higher (i.e., the change of the radius is about 10 times higher within approximately the same length) than that of the tapered GaAs NW studied in ref 23. A more fitting description of these resonances is that of volume resonances determined by the complete three-dimensional structure.…”

Section: Nano Lettersmentioning

confidence: 51%

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Far-Field Imaging for Direct Visualization of Light Interferences in GaAs Nanowires

et al. 2012

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The optical and electrical characterization of nanostructures is crucial for all applications in nanophotonics. Particularly important is the knowledge of the optical near-field distribution for the design of future photonic devices. A common method to determine optical near-fields is scanning near-field optical microscopy (SNOM) which is slow and might distort the near-field. Here, we present a technique that permits sensing indirectly the infrared near-field in GaAs nanowires via its second-harmonic generated (SHG) signal utilizing a nonscanning far-field microscope. Using an incident light of 820 nm and the very short mean free path (16 nm) of the SHG signal in GaAs, we demonstrate a fast surface sensitive imaging technique without using a SNOM. We observe periodic intensity patterns in untapered and tapered GaAs nanowires that are attributed to the fundamental mode of a guided wave modulating the Mie-scattered incident light. The periodicity of the interferences permits to accurately determine the nanowires' radii by just using optical microscopy, i.e., without requiring electron microscopy.

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Section: Nano Lettersmentioning

confidence: 51%

“…It has been shown earlier that this is a good approximation for the light scattering of individual semiconductor NWs. 21− 23 The radii of the investigated NWs are smaller than 80 nm. These NWs support only a single mode, the so-called fundamental mode.…”

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confidence: 99%

Far-Field Imaging for Direct Visualization of Light Interferences in GaAs Nanowires

et al. 2012

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“…1a-c) 26 . We find that light absorption in single standing nanowires is more than one order of magnitude more efficient than is predicted from the Lambert-Beer law.…”

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confidence: 99%

“…For low-absorbing materials (for example, indirect bandgap materials such as silicon), waveguiding effects plays a key role 23,24 , whereas highly absorbing semiconductors (such as direct-bandgap GaAs) exhibit resonances that increase the total absorption several times. Nanowires lying on a substrate also exhibit such resonances, often described by Mie theory 25,26 , although the total absorption rate is significantly lower 27,28 . Even though the optical absorption of nanowires arranged in an array has been shown to be far more complex than in thin films, nanowire vertical arrays currently seem to be the most reasonable device proposal.…”

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confidence: 99%

Single-nanowire solar cells beyond the Shockley–Queisser limit

Jørgensen²,

et al. 2013

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Light management is of great importance in photovoltaic cells, as it determines the fraction of incident light entering the device. An optimal p-n junction combined with optimal light absorption can lead to a solar cell efficiency above the Shockley-Queisser limit. Here, we show how this is possible by studying photocurrent generation for a single core-shell p-i-n junction GaAs nanowire solar cell grown on a silicon substrate. At 1 sun illumination, a short-circuit current of 180 mA cm -2 is obtained, which is more than one order of magnitude higher than that predicted from the Lambert-Beer law. The enhanced light absorption is shown to be due to a light-concentrating property of the standing nanowire, as shown by photocurrent maps of the device. The results imply new limits for the maximum efficiency obtainable with III-V based nanowire solar cells under 1 sun illumination.N anowire-based solar cells hold great promise for third-generation photovoltaics and for powering nanoscale devices 1,2 . With the advent of third-generation photovoltaics, solar cells will become cheaper and more efficient than current devices. In particular, a cost reduction may be achieved by reducing material use through the fabrication of nanowire arrays and radial p-n junctions [3][4][5] . The geometry of nanowire crystals is expected to favour elastic strain relaxation, providing great freedom in the design of new compositional multijunction solar cells 6 grown on mismatched materials 7,8 . The efficiencies of nanostructured solar cells have increased over time and have now reached up to 13.8%, due to improvements in materials and new device concepts [9][10][11][12][13][14] .Light absorption in standing nanowires is a complex phenomenon, with a strong dependence on nanowire dimensions and the absorption coefficient of the raw materials [15][16][17][18] . In low-absorbing microwire arrays, such as those composed of silicon, light absorption is understood via ray optics or by calculation of the integrated local density of optical states of the nanowire film 19,20 . Interestingly, when these arrays stand on a Lambertian back-reflector, an asymptotic increase in light trapping for low filling factors (FFs) is predicted 19 . This is advantageous for improvement of the efficiency-to-cost ratio of solar cells and has led to the demonstration of microwire arrays exhibiting higher absorption than in the equivalent thickness of textured film 19,21,22 . The case for nanowires is quite different. Nanowire diameters are smaller than or comparable to the radiation wavelength. In this case, optical interference and guiding effects play a dominant role in relation to reflectivity and absorption spectra. For low-absorbing materials (for example, indirect bandgap materials such as silicon), waveguiding effects plays a key role 23,24 , whereas highly absorbing semiconductors (such as direct-bandgap GaAs) exhibit resonances that increase the total absorption several times. Nanowires lying on a substrate also exhibit such resonances, often described by Mi...

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“…[12][13][14]17,[20][21][22][23][24][25][26][27] For example, absorption or scattering cross sections have been estimated qualitatively, 17,[20][21][22][23] while in other works wavelength-dependent photocurrent measurements performed on single NW PV devices were used to assign quantitatively the resonances of NW optical cavities. [13][14][15] Concurrent with experiments, numerical and analytical calculations of the resonant modes and key optical figures of merit (e.g.…”

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confidence: 99%

Design of Nanowire Optical Cavities as Efficient Photon Absorbers

et al. 2014

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Recent investigations of semiconductor nanowires have provided strong evidence for enhanced light absorption, which has been attributed to nanowire structures functioning as optical cavities. Precise synthetic control of nanowire parameters including chemical composition and morphology has also led to dramatic modulation of absorption properties. Here we report finite-difference time-domain (FDTD) simulations for silicon (Si) nanowire cavities to elucidate the key factors that determine enhanced light absorption. The FDTD simulations revealed that a crystalline Si nanowire with an embedded 20-nm-thick amorphous Si shell yields

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A precise optical determination of nanoscale diameters of semiconductor nanowires

Cited by 32 publications

References 25 publications

Far-Field Imaging for Direct Visualization of Light Interferences in GaAs Nanowires

Far-Field Imaging for Direct Visualization of Light Interferences in GaAs Nanowires

Single-nanowire solar cells beyond the Shockley–Queisser limit

Design of Nanowire Optical Cavities as Efficient Photon Absorbers

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