Light trapping effect of submicron surface textures in crystalline Si solar cells

Sai, Hitoshi; Kanamori, Yoshiaki; Arafune, Koji; Ohshita, Yoshio; Yamaguchi, Masafumi

doi:10.1002/pip.754

Cited by 214 publications

(121 citation statements)

References 13 publications

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“…The largest textures we measured (c ¼ 67 nm) require a height of t ¼ 440 nm (Fig. 2d, red triangles), similar to the value of 430 nm for o1% average reflectance calculated using the 12,14,27 . Calculations of the reflectance of a silicon nanotexture with an hourglass profile and alumina cap (Fig.…”

Section: Discussionsupporting

confidence: 54%

“…An alternative to thin-film-coating strategies instead patterns the interface at subwavelength dimensions, creating an effective medium between the substrate and air, with n i changing gradually from n A to n S 10,11,17 . Such structures, often called moth eyes because of their biomimicry, provide broadband antireflection over a wide range of incident light angles when subwavelength textures are taller than tB0.4 Á l and spaced closer than cBl/2n s 12,14,[18][19][20] .…”

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confidence: 99%

“…The most straightforward approach places a single layer of intermediate optical index at the interface to create destructive interference in the reflected light, providing full antireflection at a single wavelength, l ¼ 4n i Á t, with material thickness (t) and refractive index n i ¼ ffiffiffiffiffiffiffiffiffiffiffiffiffi n S Á n A p , where n S and n A are the refractive indices of the substrate and air, respectively. Increasing broadband coverage, for application in transparent window coatings [2][3][4][5] , military camouflage 6 or solar cells [7][8][9][10][11][12][13][14][15] , is possible using thin-film multilayer schemes 16 . An alternative to thin-film-coating strategies instead patterns the interface at subwavelength dimensions, creating an effective medium between the substrate and air, with n i changing gradually from n A to n S 10,11,17 .…”

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confidence: 99%

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Sub-50-nm self-assembled nanotextures for enhanced broadband antireflection in silicon solar cells

et al. 2015

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Materials providing broadband light antireflection have applications as highly transparent window coatings, military camouflage, and coatings for efficiently coupling light into solar cells and out of light-emitting diodes. In this work, densely packed silicon nanotextures with feature sizes smaller than 50 nm enhance the broadband antireflection compared with that predicted by their geometry alone. A significant fraction of the nanotexture volume comprises a surface layer whose optical properties differ substantially from those of the bulk, providing the key to improved performance. The nanotexture reflectivity is quantitatively well-modelled after accounting for both its profile and changes in refractive index at the surface. We employ block copolymer self-assembly for precise and tunable nanotexture design in the range of B10-70 nm across macroscopic solar cell areas. Implementing this efficient antireflection approach in crystalline silicon solar cells significantly betters the performance gain compared with an optimized, planar antireflection coating.

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Section: Discussionsupporting

confidence: 54%

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confidence: 99%

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confidence: 99%

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Sub-50-nm self-assembled nanotextures for enhanced broadband antireflection in silicon solar cells

et al. 2015

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“…However, such texture with large-scale pyramids is not appropriate for thin wafers due to the high Si consumption during etching and little to no optical diffraction for efficient light-trapping. In contrast, optical modeling has shown reduced surface reflection and strong diffraction for effective light-trapping in thin wafers only when grating textures are reduced to feature size comparable with the wavelength [4]. Although various textures consisting of rods [5,6], cones [6], inverted-pyramids [7], holes (honey-comb structure) [8], grooves [9], etc.…”

Section: Introductionmentioning

confidence: 99%

Ultrafast laser direct hard-mask writing for high efficiency c-Si texture designs

et al. 2013

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This study reports a high-resolution hard-mask laser writing technique to facilitate the selective etching of crystalline silicon (c-Si) into an inverted-pyramidal texture with feature size and periodicity on the order of the wavelength which, thus, provides for both anti-reflection and effective light-trapping of infrared and visible light. The process also enables engineered positional placement of the invertedpyramid thereby providing another parameter for optimal design of an optically efficient pattern. The proposed technique, a non-cleanroom process, is scalable for large area micro-fabrication of high-efficiency thin c-Si photovoltaics. Optical wave simulations suggest the fabricated textured surface with 1.3 μm inverted-pyramids and a single anti-reflective coating increases the relative energy conversion efficiency by 11% compared to the PERL-cell texture with 9 μm inverted pyramids on a 400 μm thick wafer. This efficiency gain is anticipated to improve further for thinner wafers due to enhanced diffractive light trapping effects.

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“…21 In this paper, we demonstrate significantly increased absorption in a thin active layer for PV systems working under solar concentration. We consider a metal back mirror and front sawtooth grating [22][23][24] made of SiC together with a thin GaSb layer.…”

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Dielectric gratings for wide-angle, broadband absorption by thin film photovoltaic cells

Esteban

Laroche

Greffet

2010

Applied Physics Letters

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Optical management is essential to increase absorption in thin photovoltaic cells. In this article, full electromagnetic simulations show that a back mirror and a one-dimensional front SiC sawtooth grating of ∼1 μm dimensions can significantly increase absorption in a thin layer under light concentration. A 50 nm thick GaSb active layer in the described configuration absorbs ∼66% of the incident solar photons above the band gap for a concentration equivalent to a numerical aperture NA=1/2. This absorption represents a ∼76% or 26% increase over the same structure but with the grating removed or substituted by an ideal antireflection coating, respectively.

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Light trapping effect of submicron surface textures in crystalline Si solar cells

Cited by 214 publications

References 13 publications

Sub-50-nm self-assembled nanotextures for enhanced broadband antireflection in silicon solar cells

Sub-50-nm self-assembled nanotextures for enhanced broadband antireflection in silicon solar cells

Ultrafast laser direct hard-mask writing for high efficiency c-Si texture designs

Dielectric gratings for wide-angle, broadband absorption by thin film photovoltaic cells

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