Light management design in ultra-thin chalcopyrite photovoltaic devices by employing optical modelling

Kovačič, Milan; Krč, Janez; Lipovšek, Benjamin; Chen, W.-C.; Edoff, Marika; Bolt, P.J.; Deelen, J. van; Zhukova, Maria; Lontchi, Jackson; Flandre, Denis; Salomé, Pedro M. P.; Topič, Marko

doi:10.1016/j.solmat.2019.109933

Cited by 24 publications

(18 citation statements)

References 47 publications

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“…A key technique for obtaining good light trapping and enhancing the efficiency of solar cells is to engineer the light behavior by using photonic crystals, 4 diffraction gratings, 5 anti-reection coatings, 6 surface texturing, 7 and metallic nanoparticles. 3,8 Plasmonic nanogratings among other structures show a substantial progress as they can be used either as an innovative back reector patterned on a metal mirror [9][10][11][12] and/or on transparent and conductive oxides (TCO), [13][14][15][16] to improve both the optical path length and optical absorption over a broad spectrum. The effective coupling between metallic nanograting modes and the incident light essentially presents an efficient light trapping developing from surface plasmon resonances and their resultant near-eld light concentration.…”

Section: Introductionmentioning

confidence: 99%

Efficient broadband light absorption in thin-film a-Si solar cell based on double sided hybrid bi-metallic nanogratings

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Efficient broadband light absorption in thin-film a-Si solar cell based on double sided hybrid bi-metallic nanogratings

et al. 2020

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“…FEM enables modelling of the exact morphology of (periodic) nanotextured interfaces in three dimensional structures. Such rigorous analysis in combination with realistic complex refractive indices of materials [12] enables to include various effects in simulation, such as light scattering and anti-reflection due to nanotexturing, as well as plasmonic absorption that can occur at textured metallic surfaces. However, it only considers coherent propagation of light in thin layers.…”

Section: Modelling and Simulationsmentioning

confidence: 99%

“…As lateral dimensions of the structures are expected to be much larger than vertical ones, edge effects in simulations are neglected (but are possible to be included). All models were calibrated according to the literature [12] and measurement results -see Section 5.…”

Section: Modelling and Simulationsmentioning

confidence: 99%

“…To improve optical performance of thin CIGS, in addition to alternative highly reflective BR, we also introduce internal nano-textures and external microtextures (LM foil) in simulations. The position of the internal and external textures can be seen in Figure 1(a), while its shape and size can be seen in Figure 1 In our previous work, a detailed optical analysis of different internal textures introduced at the rear side of the device was performed [12], thus here we only use an optimal texture in our analysis. We selected a periodic two-dimensional, sine-like nano-texture with P = 800 nm and h = 300 nm (see inset of Figure 1(b)), that can be fabricated on silicon or glass master by e-beam or etching techniques [19].…”

Section: Device Structure and Texturesmentioning

confidence: 99%

“…By optimization of the LM foil texture (e.g. aspect ratio) or by using different textures, even higher J sc could be achieved [12].…”

Section: External Texturesmentioning

confidence: 99%

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Modelling Supported Design of Light Management Structures in Ultra-Thin Cigs Photovoltaic Devices

2019

Informacije MIDEM

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Chalcopyrite solar cells exhibit one of the highest conversion efficiencies among thin-film solar cell technologies (> 23.3%), however a considerably thick absorber ≥1.8 µm is required for an efficient absorption of the long-wavelength light and collection of charge carriers. In order to minimize the material consumption and to accelerate the fabrication process, further thinning down of the absorber layer is important. Using a thin absorber layer results in a highly reduced photocurrent density and to compensate for it an effective light management needs to be introduced. Experimentally supported, advanced optical simulations in a PV module configuration, i.e. solar cell structure including the encapsulation and front glass are employed to design solutions to increase the short current density of devices with ultra-thin (500 nm) absorbers. In particular (i) highly reflective metal back reflector (BR), (ii) internal nano-textures and (iii) external textures by applying a light management (LM) foil are investigated by simulations. Experimental verification of simulation results is presented for the external texture case. In the scope of this contribution we show that any individual aforementioned approach is not sufficient to compensate for the short circuit current drop of the thin CIGS, but only a combination of highly reflective back contact and introduction of textures (internal or external) is able to compensate and also to exceed (by more than 5 % for internal texture) photocurrent density of a thick (1800 nm) CIGS absorber.

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Exploiting the Optical Limits of Thin‐Film Solar Cells: A Review on Light Management Strategies in Cu(In,Ga)Se₂

Oliveira

Teixeira

Ramos

et al. 2022

Advanced Photonics Research

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Light management strategies are of utmost importance to allow Cu(In,Ga)Se2 (CIGS) technology market expansion, as it would enable a conversion efficiency boost as well as thinner absorber layers, increasing sustainability and reducing production costs. However, fabrication and architecture constraints hamper the direct transfer of light management architectures from other photovoltaic technologies. The demand for light management in thin and ultrathin CIGS cells is analyzed by a critical description of the optical loss mechanisms in these devices. Three main pathways to tackle the optical losses are identified: front light management architectures that assist for an omnidirectional low reflection; rear architectures that enable an enhanced optical path length; and unconventional spectral conversion strategies for full spectral harvesting. An outlook over the challenges and developments of light management architectures is performed, establishing a research roadmap for future works in light management for CIGS technology. Following the extensive review, it is expected that combining antireflection, light trapping, and conversion mechanisms, a 27% CIGS solar cell can be achieved.

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Light management design in ultra-thin chalcopyrite photovoltaic devices by employing optical modelling

Cited by 24 publications

References 47 publications

Efficient broadband light absorption in thin-film a-Si solar cell based on double sided hybrid bi-metallic nanogratings

Efficient broadband light absorption in thin-film a-Si solar cell based on double sided hybrid bi-metallic nanogratings

Modelling Supported Design of Light Management Structures in Ultra-Thin Cigs Photovoltaic Devices

Exploiting the Optical Limits of Thin‐Film Solar Cells: A Review on Light Management Strategies in Cu(In,Ga)Se₂

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Light management design in ultra-thin chalcopyrite photovoltaic devices by employing optical modelling

Cited by 24 publications

References 47 publications

Efficient broadband light absorption in thin-film a-Si solar cell based on double sided hybrid bi-metallic nanogratings

Efficient broadband light absorption in thin-film a-Si solar cell based on double sided hybrid bi-metallic nanogratings

Modelling Supported Design of Light Management Structures in Ultra-Thin Cigs Photovoltaic Devices

Exploiting the Optical Limits of Thin‐Film Solar Cells: A Review on Light Management Strategies in Cu(In,Ga)Se2

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Product

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Exploiting the Optical Limits of Thin‐Film Solar Cells: A Review on Light Management Strategies in Cu(In,Ga)Se₂