Light Harvesting in Silicon Nanowires Solar Cells by Using Graphene Layer and Plasmonic Nanoparticles

Elrashidi, Ali

doi:10.3390/app12052519

Cited by 15 publications

(7 citation statements)

References 28 publications

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“…The most important step in this fabrication process is to make the sidewalls of the ring-shaped pillars vertical to guarantee that no metals were deposited on the sidewalls during evaporation [ 34 ]. Table 1 compares the proposed plasmonic metamaterial absorber to structures documented in the literature, fabricated structures, and simulated work [ 26 , 36 , 38 ]. Regarding the reported absorber in this paper, it is very competitive due to its higher absorption and relative absorption bandwidth.…”

Section: Resultsmentioning

confidence: 99%

Investigating the Absorption Spectra of a Plasmonic Metamaterial Absorber Based on Disc-in-Hole Nanometallic Structure

Mahros

Alharbi

2022

Nanomaterials

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In this work, we present and explore the characteristics of a plasmonic metamaterial absorber based on a metal–insulator–metal functional stack. The proposed structure consists of glass “sandwiched” between a silver reflector and a titanium metallic disc, embedded inside a Ti periodic nano-hole array, as an outside layer. In the visible and infrared regimes, the optical absorption spectra of such structures have been investigated using the finite difference time domain method. The impact of modifying nano-hole and embedded disc diameters on the absorber’s performance has been investigated. Changing these two distinct structural parameters tunes the coupling effect between the localized and propagating surface plasmons. The adequate bandwidth, average spectral absorption rate, and short circuit current density are calculated to determine the performance of the designated absorber. The proposed structure of the plasmonic metamaterial absorber reaches an average absorption of over 94% in a bandwidth of 0.81 µm and near-perfect absorption of 98% around the wavelength of 0.7 µm, with an almost 100% relative absorption bandwidth and 41 mA/cm2 short circuit current density. In addition, the results show that the disc-in-hole absorber’s structural parameters can be changed precisely and facilely to tailor to the absorption spectra.

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Section: Resultsmentioning

confidence: 99%

Investigating the Absorption Spectra of a Plasmonic Metamaterial Absorber Based on Disc-in-Hole Nanometallic Structure

Mahros

Alharbi

2022

Nanomaterials

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“…The fabrication process needed here has been reported for both Silicon 31 and Ge 51 solar cells and we expect that this concept can be used in PVSC using other semiconductor materials for multijunctions, such as Si with GaAs or perovskite tandem solar cells. Similarly, this concept can be applied to other innovative approaches, such as using a thin graphene layer to increase absorption further 63 or energy downshifting to absorb more solar energy from a wider solar spectrum. 64 We believe that the performance of these designs can be further enhanced by using even a much thinner layer by adopting the concept of mimicking multiple ARC layers presented here by using NWs of different diameters while reducing material waste and costs.…”

Section: Discussionmentioning

confidence: 99%

Optical and electrical characterization of solar cell with nanowires mimicking antireflection coating layers considering axial and radial PN junctions

Cabrera‐España,

Kamuka,

Khaled

et al. 2024

Energy Science & Engineering

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It has been well documented that the usage of a textured cover layer reduces reflection from the air‐solar cell interface, which ultimately enhances the power conversion efficiency (PCE) of a solar cell. The most commonly used patterns, such as pyramids, micropillars, nanowires (NW), and nanoholes have been widely studied and optimized. Besides using such NWs to enhance light absorption, this work also additionally considers the concept of mimicking the antireflection coating of single or multiple layers in minimizing the reflectance and thus enhancing the total absorptance further. It is shown here that at least one order of magnitude shorter multilayer NW pattern of 268 nm total height can outperform a standard NW of 4270 nm height, which needs less material and can also be fabricated at a reduced cost. Furthermore, the proposed design with reduced height has a significantly lower surface‐to‐volume ratio, which also reduces surface recombination loss than the other textured surface patterns. The results presented in this work have been comprehensively analyzed by initially optimizing optical absorption and then completing the electrical simulations. The optimized design in conjunction with a back reflector offers an efficiency as high as 16.434%.

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“…Plasmonic nanoparticles distributed on the (ZnO) layer is changing the absorbed optical power inside, which depends on the maximum value of reflectivity. (NP) shape is the main parameter on the transmitted optical power, as well as the relative permittivity of the plasmonic (NPs) and dielectric constant of the surrounded medium [ 25 ]. The maximum absorption occurred at the maximum value of the wavelength, which can be calculated using Equation (7).…”

Section: Modeling and Simulation Analysis Of The Fabricated Structurementioning

confidence: 99%

“…Hence, the dielectric permittivity can be expressed by using a multi-oscillator Drude–Lorentz model [ 25 ], as given in Equation (8):

where ( ε ∞ ) is the plasmonic high frequency dielectric permittivity, ( ω D ) and ( γ D ) are the plasma and collision frequencies of the free electrons, ( δ k ) is the amplitude of Lorentz oscillator, ( ω k ) is the resonance angular frequencies and ( γ k ) is the damping constants for ( k ) value from one to six.…”

Section: Modeling and Simulation Analysis Of The Fabricated Structurementioning

confidence: 99%

“…(Au NPs) behave like a nanoantenna, which absorb the incident light and retransmit it into the structure, where peak wavelength of the absorbed light is depending on the (Au NPs) size and periodicity as given in Equation (7). Changing the plasmonic material will change the peak maximum wavelength to different range according to the Drude–Lorentz model [ 25 ]. For (Au NPs), the maximum peak occurs at 400 nm in addition to other shifted peaks, according to the (Au NPs) radius as illustrated in Figure 10 .…”

Section: Modeling and Simulation Analysis Of The Fabricated Structurementioning

confidence: 99%

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Analyzing the Mechanism of Zinc Oxide Nanowires Bending and Bundling Induced by Electron Beam under Scanning Electron Microscope Using Numerical and Simulation Analysis

et al. 2022

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The bending effect of self-catalyst zinc oxide nanowires on a photoconducting behavior has been investigated by in-situ scanning electron microscope method and interpreted by analytical modeling. Zinc oxide NWs tend to incline due to geometric instability and because of the piezoelectric properties, which was confirmed by scanning electron microscope images. A cantilever bending model adequately describes the bending and bundling events, which are linked to the electrostatic interaction between nanowires. The light absorption of zinc oxide nanowires in the visible and near infrared bands has been modelled using the finite difference time domain method. The influence of the density of nanowires (25%, 50%, 75%) and the integration of plasmonic nanoparticles distributed on the seed layer (with varied radii) on the light absorption of zinc oxide nanowires was studied using simulation analysis. We have shown that the geometry of zinc oxide nanowires in terms of length, separation distance, and surface charge density affects the process of zinc oxide nanowires bending and bundling and that absorption will be maximized by integrating Au plasmonic nanoparticles with a radius of 10 nm.

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Light Harvesting in Silicon Nanowires Solar Cells by Using Graphene Layer and Plasmonic Nanoparticles

Cited by 15 publications

References 28 publications

Investigating the Absorption Spectra of a Plasmonic Metamaterial Absorber Based on Disc-in-Hole Nanometallic Structure

Investigating the Absorption Spectra of a Plasmonic Metamaterial Absorber Based on Disc-in-Hole Nanometallic Structure

Optical and electrical characterization of solar cell with nanowires mimicking antireflection coating layers considering axial and radial PN junctions

Analyzing the Mechanism of Zinc Oxide Nanowires Bending and Bundling Induced by Electron Beam under Scanning Electron Microscope Using Numerical and Simulation Analysis

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