Strategy for tailoring the size distribution of nanospheres to optimize rough backreflectors of solar cells

Nanz, Stefan; Abass, Aimi; Piechulla, Peter M.; Sprafke, Alexander; Wehrspohn, Ralf B.; Rockstuhl, Carsten

doi:10.1364/oe.26.00a111

Cited by 10 publications

(8 citation statements)

References 44 publications

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“…This radial enhancement mimics the isotropic growth process of the ALD layer. The resulting height profile was previously already analyzed for the purpose of being used as a metallic back reflector in solar cells . Here, we add another crucial step: the height profile is taken as the inverse of the nanosphere monolayer.…”

Section: Strategy and Simulationsmentioning

confidence: 99%

“…The resulting height profile was previously already analyzed for the purpose of being used as a metallic back reflector in solar cells. [29] Here, we add another crucial step: the height profile is taken as the inverse of the nanosphere monolayer. With this, the finer texture features with smaller radii of curvature are more exposed.…”

Section: Strategy and Simulationsmentioning

confidence: 99%

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Light‐Trapping Front Textures for Solar Cells from Tailored Mixtures of Nanospheres: A Numerical Study

Nanz

Abass

Piechulla

et al. 2018

Physica Status Solidi (a)

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Highly efficient anti‐reflection textures for solar cells that allow a fabrication using a two‐step bottom‐up approach are reported. Hereby, nanospheres of tailored sizes are deposited as a monolayer on a substrate and the resulting height profile is used as a template for structuring the silicon surface. By applying these textures to crystalline silicon solar cells, it is numerically shown that such interfaces provide excellent broadband suppression of reflection while also enhancing the effective path‐length through oblique‐angle scattering into the medium. Reflectance values around 5% can be reached and sustained for incident angles up to 40°. The short‐circuit current density obtained with the disordered texture and assuming two‐pass absorption in 10 µm thick crystalline silicon reaches 25.3 mA cm−2, which is close to the corresponding value achievable with a Lambertian texture (27.9 mA cm−2). Considering the simplicity and low cost of the approach, these textures may serve as a promising alternative to other often used anti‐reflection textures, especially for large‐scale devices.

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Section: Strategy and Simulationsmentioning

confidence: 99%

Section: Strategy and Simulationsmentioning

confidence: 99%

Light‐Trapping Front Textures for Solar Cells from Tailored Mixtures of Nanospheres: A Numerical Study

Nanz

Abass

Piechulla

et al. 2018

Physica Status Solidi (a)

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“…[29,30] Tailored nanostructures are also very promising materials for the enhancement of the efficiency of solar cells via light trapping and plasmonic scattering mechanisms. [31,32] In this work, we demonstrate an application of DLIP for the fabrication of 1D periodic structures with subwavelength features in amorphous hydrogenated DLC (a-C:H, further in the text DLC) nanocomposite thin films with embedded silver nanoparticles (DLC:Ag, 7.9-14.1 at% Ag). We have varied the energy densities (laser fluence Φ ¼ 1-145 mJ cm À2 , number of pulses N ¼ 1000-125 000) of ytterbium doped potassium gadolinium tungstate (Yb:KGW) femtosecond-laser second harmonic irradiation to determine ablation and patterning thresholds, and have analyzed incubation effects together with the resulting modifications of silver nanoparticle's effective diameter size distributions.…”

Section: Introductionmentioning

confidence: 99%

“…The arrangement of nanoparticles in diffraction grating‐like periodic structures modifies the effective refractive index and alters the diffraction efficiency of the periodic structure, which is required to be as high as possible for the most optical applications, especially for increased sensitivity of plasmonic diffractive optical sensors and resonator structures . Tailored nanostructures are also very promising materials for the enhancement of the efficiency of solar cells via light trapping and plasmonic scattering mechanisms …”

Section: Introductionmentioning

confidence: 99%

Tailoring of Silver Nanoparticle Size Distributions in Hydrogenated Amorphous Diamond‐Like Carbon Nanocomposite Thin Films by Direct Femtosecond Laser Interference Patterning

et al. 2019

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Patterning of nanocomposites by conventional lithography processes is problematic due to the different physical properties of matrix and filler. Direct laser interference patterning (DLIP) promises rapid micromachining of virtually any material with subwavelength resolution. A control of intense laser light modifies the filler particle size distribution in nanocomposite films. Herein, DLIP of periodic patterns with half‐pitch <1 μm in reactive magnetron‐sputtered hydrogenated amorphous diamond‐like carbon nanocomposite thin films with embedded silver nanoparticles (DLC:Ag) is demonstrated. Periodic patterns of regularly repeating areas with modified size distributions of silver nanoparticles are obtained by a variation of fluences and number of pulses of 515 nm wavelength femtosecond laser. Depending on the silver content in nanocomposite films, nanoparticle size distributions are either bimodal (for 14.1 at% Ag containing films) or unimodal (7.9 at%) with effective average diameters shifting from 13 to 69 nm, depending on the laser processing parameters. The importance of localized surface plasmon absorption and localized field enhancement at the DLC–Ag interface for lowering the ablation threshold of DLC:Ag nanocomposites below 6 mJ cm−2 at 1000 pulses is demonstrated. This is at least four times lower than the threshold for pure DLC obtained using the same DLIP setup.

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“…Having on-demand large-area interfaces with desired light interaction is a long-standing vision in the field of optics. Such interfaces have a plethora of applications for various optoelectronic devices, such as solar cells or OLEDs [1][2][3] . For many of these applications, not only that the interfaces should operate optimally in providing a desired scattering response, they should also operate either over an extended spectral domain or with a wide acceptance angle.…”

Section: Introductionmentioning

confidence: 99%

Perturbing beyond the shallow amplitude regime: Green’s function scattering formalism with Bloch modes

et al. 2019

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We present a Bloch modes' based Green's function scattering formalism for cost efficient forward modelling of disordered binary surface textures. The usage of Bloch modes of an unperturbed reference ordered system as ansatz allows our formalism to address surface scattering beyond the shallow amplitude regime. The main advantage of our formalism is the possibility to utilize a small amount of plane waves to represent the assumed Bloch modes thereby reducing computational costs, while still allowing one to estimate the scattering response to all channels accessible by the disordered system. Benchmarking calculations discussed in the paper demonstrate how the usage of our Bloch modes ansatz provides an excellent estimate of the scattering response over an important regime of disorder. As an example of our method's strength, we examine an electrically decoupled binary light trapping texture and demonstrate how introducing disorder may improve light incoupling into the considered solar cell structure. arXiv:1809.00195v1 [physics.optics] 1 Sep 2018

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Strategy for tailoring the size distribution of nanospheres to optimize rough backreflectors of solar cells

Cited by 10 publications

References 44 publications

Light‐Trapping Front Textures for Solar Cells from Tailored Mixtures of Nanospheres: A Numerical Study

Light‐Trapping Front Textures for Solar Cells from Tailored Mixtures of Nanospheres: A Numerical Study

Tailoring of Silver Nanoparticle Size Distributions in Hydrogenated Amorphous Diamond‐Like Carbon Nanocomposite Thin Films by Direct Femtosecond Laser Interference Patterning

Perturbing beyond the shallow amplitude regime: Green’s function scattering formalism with Bloch modes

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