Multi-layering of a nanopatterned TiO2 layer for highly efficient solid-state solar cells

Na, Jongbeom; Kim, Young-Hoon; Park, Chihyun; Kim, Eunkyoung

doi:10.1038/am.2015.105

Cited by 12 publications

(8 citation statements)

References 28 publications

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“…Abstraction of a hydrogen radical from the neighborhood thiol to this carbon radical accomplishes the hydrothiolation, while simultaneously propagating the chain reaction. 9,17 Fabrication of micro/nanostructures of oxides is of paramount importance in various applications including photoelectrochemical cells, 18 photovoltaic cells, 19 sensors, 20 and catalysis. 21 Several techniques including photolithography, 22,23 electron-beam lithography, 24,25 electro-hydrodynamic lithography, 26,27 direct write assembly, 28 selective surface wetting, 29 dip-pen nanolithography, 30,31 nanoimprint lithography (NIL) [32][33][34] among others 35,36 have been utilized towards fabrication of metal oxide micro/nanostructures.…”

Section: Introductionmentioning

confidence: 99%

Oxygen insensitive thiol–ene photo-click chemistry for direct imprint lithography of oxides

2018

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Section: Introductionmentioning

confidence: 99%

Oxygen insensitive thiol–ene photo-click chemistry for direct imprint lithography of oxides

2018

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“…4 The effect of filling factor and slanted angle of diffraction gratings on reflectance and the analysis of diffracted light: a The reflectance with respect to filling factor when refractive index of electrolyte is from 1.00 to 1.35. b The amount of two lights passing through electrode (bold yellow line) and electrolyte (bold blue line) on the condition of F = 0.1 or smaller than 0.1. c The destructive interference of two lights, the one passes through electrolyte (bold blue line) and the other propagates laterally at the interface region 3 and region 1 (bold red line) on the condition of F = 0.1 or smaller than 0.1. d The reflectance with respect to slanted angle when refractive index of electrolyte is from 1.00 to 1.35 (color figure online) Fig. 5 The reflectance according to wavelength with optimal grating (purple line), without grating (black line), with diffraction grating developed by Kim [23] and Na [24] (color figure online) of N-719 dye is around 925, 783 and 1975% compared to previous researches and without gratings.…”

Section: The Improvement Of Reflectance Compared To Previous Researchesmentioning

confidence: 97%

“…Based on analysis of interference of diffracted light, the amount of destructive interference on the condition θ = 90° is greater than any other conditions. [23] and Na [24]. Due to the selective reflectance of the diffraction grating what we designed, the transparent characteristics of DSSC make them suitable for outdoor applications, particularly for use as building integrated photovoltaic devices, where power supplying device replace conventional building materials such as window glass.…”

Section: The Effect Of Filling Factor Of Diffraction Gratings On Reflmentioning

confidence: 99%

“…However, the optimized design of the diffraction grating of the standard solar cells does not valid to the DSSCs systems due to the different selection of the electrode and the electrolyte. A recent study proposed the DSSC system that employs the diffraction grating to improve the conversion efficiency [23][24][25]. However, they only focused on the methods of fabricating diffraction gratings, not the optimal design of diffraction gratings.…”

Section: Introductionmentioning

confidence: 99%

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Geometric Effect of Grating-Patterned Electrode for High Conversion Efficiency of Dye-Sensitized Solar Cells

Lee

Moon

et al. 2019

Multiscale Sci. Eng.

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Photovoltaic devices that convert solar energy into electrical energy are a promising solution to resolve environmental problems the world is facing today. Among the various photovoltaic system, dye-sensitized solar cells (DSSCs) has been regarded as a new generation of the photovoltaic device due to the low cost and simple fabrication process. However, the current design of DSSCs shows insufficient conversion efficiency. To solve this problem, we increase the optical path length by trapping the incident light using a diffraction grating with high reflectance. We numerically investigate the effect of geometric parameters on the reflectance of diffraction gratings in DSSC system. Based on the simulation results, we propose an optimized geometry of diffraction grating that reflects the outgoing light and traps the incident light. The optimized geometry of the diffraction grating increase in the reflectance about 80% when it is compared to that without the diffraction grating.

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“…Periodic nanostructured gratings have been extensively explored for light trapping in various types of thin-film solar cells and various silicon or metamaterial-based structures have been proposed, such as nanopillar, nanowire, nanohole, and pyramid arrays [ 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 ]. The downside, however, is that these structures are difficult to fabricate due to their complicated structures or material compositions.…”

Section: Introductionmentioning

confidence: 99%

Numerical Study of Complementary Nanostructures for Light Trapping in Colloidal Quantum Dot Solar Cells

et al. 2016

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We have investigated two complementary nanostructures, nanocavity and nanopillar arrays, for light absorption enhancement in depleted heterojunction colloidal quantum dot (CQD) solar cells. A facile complementary fabrication process is demonstrated for patterning these nanostructures over the large area required for light trapping in photovoltaic devices. The simulation results show that both proposed periodic nanostructures can effectively increase the light absorption in CQD layer of the solar cell throughout the near-infrared region where CQD solar cells typically exhibit weak light absorption. The complementary fabrication process for implementation of these nanostructures can pave the way for large-area, inexpensive light trapping implementation in nanostructured solar cells.

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Multi-layering of a nanopatterned TiO2 layer for highly efficient solid-state solar cells

Cited by 12 publications

References 28 publications

Oxygen insensitive thiol–ene photo-click chemistry for direct imprint lithography of oxides

Oxygen insensitive thiol–ene photo-click chemistry for direct imprint lithography of oxides

Geometric Effect of Grating-Patterned Electrode for High Conversion Efficiency of Dye-Sensitized Solar Cells

Numerical Study of Complementary Nanostructures for Light Trapping in Colloidal Quantum Dot Solar Cells

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