Electromagnetic field enhancement effects in group IV semiconductor nanowires. A Raman spectroscopy approach

Pura, José Luis; Anaya, J.; Souto, J.; Prieto, Á. C.; Rodrı́guez, A.; Rodrı́guez, T.; Periwal, P.; Baron, T.; Jiménez, J.

doi:10.1063/1.5012987

Cited by 7 publications

(20 citation statements)

References 41 publications

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“…In ref. one can see the spectrum at the HJ of a SiGe/Si axially heterostructured NW with higher concentration of Ge (60%), where one can clearly appreciate the HJ contribution.…”

Section: Resultsmentioning

confidence: 98%

“…This model is solved by FEMs using COMSOL Multiphysics. The Maxwell equations are solved for the NW and its surrounding space when excited by a focused laser beam in similar conditions to the micro‐Raman experiments . The system formed by the air/NW/substrate was limited by cartesian perfectly matched layers (PMLs), which absorb the outgoing radiation eliminating secondary reflections, Figure .…”

Section: Resultsmentioning

confidence: 99%

“…The presence of the axial heterojunction breaks the longitudinal symmetry of the NW. Therefore, a 3D model must be applied, instead of the 2D model used for NWs without axial discontinuities, either homogeneous NWs or core/shell heterostructured NWs . The 3D model accounts for the presence of the axial HJ; and also takes account of the finite length of the NW.…”

Section: Resultsmentioning

confidence: 99%

“…The Raman spectra were acquired by scanning the laser beam along the NW axis in steps of 100 nm, and under TM light polarization with respect to the NW axis, that is, the electric field parallel to the NW axis. This orientation is selected because the NWs behave as electric dipoles face to the incident laser beam, and the Raman intensity as a function of the angle formed by the NW axis and the light polarization axis reveals an electric dipole behavior . The maximum Raman signal is therefore obtained for TM polarization with respect to the NW axis.…”

Section: Methodsmentioning

confidence: 99%

“…In our Raman experiments we used an Al substrate, which permits the optimization of the Raman signal, but also acts as an efficient heat‐sink avoiding the NW heating. The laser power was optimized to prevent any heating on the NWs . The Raman measurements were carried out under laser power densities around 5 × 10 8 W m −2 , for which laser heating was negligible.…”

Section: Methodsmentioning

confidence: 99%

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About the Interaction Between a Laser Beam and Group IV Nanowires: A Study of the Electromagnetic Field Enhancement in Homogeneous and Heterostructured Nanowires

Pura

Anaya

Jiménez

2018

Physica Status Solidi (a)

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The optical properties of semiconductor nanowires (NWs) are object of study because they are the building blocks of the future nanophotonic devices. The high refractive index and its reduced dimension, make them suitable for photon engineering. The study of the interaction between NWs and visible light has revealed resonances of the light absorption/scattering by the NWs. Micro‐Raman spectroscopy is used as a characterization method of semiconductor NWs. The relation between the Raman intensity and the incident electromagnetic (EM) field permits to study the light/NW interaction through the micro‐Raman spectra of individual NWs. As compared to either metallic or dielectric NWs, the semiconductor NWs add additional tools to modify its interaction with light, for example, the composition, the presence of heterostructures, both axial and radial, doping, and the surface morphology. One presents herein a study of the optical response of group IV semiconductor NWs to visible photons. The study is experimentally carried out through the micro‐Raman spectroscopy of different group IV NWs, both homogeneous and heterostructured (SiGe/Si), and the results are analyzed in terms of the EM modeling of the light/NW interaction using finite element methods (FEMs). The heterostructures are seen to produce additional resonances allowing new photonic capacities to the semiconductor NWs.

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“…In ref. one can see the spectrum at the HJ of a SiGe/Si axially heterostructured NW with higher concentration of Ge (60%), where one can clearly appreciate the HJ contribution.…”

Section: Resultsmentioning

confidence: 98%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 3 more Smart Citations

About the Interaction Between a Laser Beam and Group IV Nanowires: A Study of the Electromagnetic Field Enhancement in Homogeneous and Heterostructured Nanowires

Pura

Anaya

Jiménez

2018

Physica Status Solidi (a)

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Composition, Optical Resonances, and Doping of InP/InGaP Nanowires for Tandem Solar Cells: a Micro-Raman Analysis

Mediavilla,

Pura,

Hinojosa

et al. 2024

ACS Nano

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We present a micro-Raman study of InP/InGaP tandem junction photovoltaic nanowires. These nanowires render possible InGaP compositions that cannot be made in thin films due to strain. The micro-Raman spectra acquired along the nanowires reveal the existence of compositional changes in the InGaP alloy associated with the doping sequence. The heavily Zn-doped In x Ga1–x P (x is the In molar fraction) side of the tunnel diode is Ga rich, x = 0.25, with respect to the n-type and intrinsic segments of the top cell, which are close to the nominal composition of the NWs (x = 0.35). The p-type end segment is still Ga-rich. Electromagnetic resonances are observed in the tunnel diode. The Raman signal arising from the InGaP side of the tunnel diode is significantly enhanced. This enhancement permits the observation of a Raman mode that can be associated with an LO phonon plasmon coupled mode (LOPCM). This mode has not been previously reported in the literature of InGaP, and it permits the Raman characterization of the tunnel diode. The analysis of this mode and its relation to the LO phonon modes of the alloy, InP-like and GaP-like, allows to establish an apparent one-mode behavior for the phonon plasmon coupling. It indicates that hole plasma couples to the GaP-like LO mode. The LOPCMs are modeled using the Lindhard Mermin formalism for the dielectric function.

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Electromagnetic enhancement effect on the atomically abrupt heterojunction of Si/InAs heterostructured nanowires

Pura

Magdaleno

Muñoz-Segovia

et al. 2019

Journal of Applied Physics

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Semiconductor nanowires (NWs) present a great number of unique optical properties associated with their reduced dimension and internal structure. NWs are suitable for the fabrication of defect free Si/III-V heterostructures, allowing the combination of the properties of both Si and III-V compounds. We present here a study of the electromagnetic (EM) resonances on the atomically abrupt heterojunction of Si/InAs axially heterostructured NWs. We studied the electromagnetic response of Si/InAs heterojunctions sensed by means of Micro-Raman spectroscopy. These measurements reveal a high enhancement of the Si Raman signal when the incident laser beam is focused right on the Si/InAs interface. The experimental Raman observations are compared to finite element methods (FEM) simulations for the interaction of the focused laser beam with the heterostructured NW. The simulations explain why the enhancement is detected on the Si signal when illuminating the HJ and also provide a physical framework to understand the interaction between the incident

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Electromagnetic field enhancement effects in group IV semiconductor nanowires. A Raman spectroscopy approach

Cited by 7 publications

References 41 publications

About the Interaction Between a Laser Beam and Group IV Nanowires: A Study of the Electromagnetic Field Enhancement in Homogeneous and Heterostructured Nanowires

About the Interaction Between a Laser Beam and Group IV Nanowires: A Study of the Electromagnetic Field Enhancement in Homogeneous and Heterostructured Nanowires

Composition, Optical Resonances, and Doping of InP/InGaP Nanowires for Tandem Solar Cells: a Micro-Raman Analysis

Electromagnetic enhancement effect on the atomically abrupt heterojunction of Si/InAs heterostructured nanowires

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