Light-trapping enhanced thin-film III-V quantum dot solar cells fabricated by epitaxial lift-off

Cappelluti, Federica; Kim, Dongyoung; Eerden, Maarten van; Cédola, Ariel Pablo; Aho, Timo; Bissels, G.M.M.W.; Elsehrawy, Farid; Wu, Jiang; Liu, Huiyun; Mulder, P.; Bauhuis, G.J.; Schermer, J.J.; Niemi, Tapio; Guina, Mircea

doi:10.1016/j.solmat.2017.12.014

Cited by 23 publications

(12 citation statements)

References 53 publications

(93 reference statements)

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“…In these structures, the bottom subcell consists of thin‐film GaAs, which has demonstrated the highest conversion efficiency among all types of single junction solar cells . Additionally to back contact design strategies, the position of the junction in GaAs cells has been identified as an important parameter, showing that a device with the junction closer to the bottom of n‐on‐p cells allows for operation in the radiative recombination regime . This type of cell, therefore, has a higher open circuit voltage and is preferred over the standard structure with a junction located closer to the front.…”

Section: Introductionmentioning

confidence: 99%

Electron radiation–induced degradation of GaAs solar cells with different architectures

Gruginskie

Cappelluti

Bauhuis

et al. 2020

Progress in Photovoltaics

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The effects of electron irradiation on the performance of GaAs solar cells with a range of architectures is studied. Solar cells with shallow and deep junction designs processed on the native wafer as well as into a thin‐film were irradiated by 1‐MeV electrons with fluence up to 1×1015 e−/cm2. The degradation of the cell performance due to irradiation was studied experimentally and theoretically using model simulations, and a coherent set of minority carriers' lifetime damage constants was derived. The solar cell performance degradation primarily depends on the junction depth and the thickness of the active layers, whereas the material damage shows to be insensitive to the cell architecture and fabrication steps. The modeling study has pointed out that besides the reduction of carriers lifetime, the electron irradiation strongly affects the quality of hetero‐interfaces, an effect scarcely addressed in the literature. It is demonstrated that linear increase with the electron fluence of the surface recombination velocity at the front and rear hetero‐interfaces of the solar cell accurately describes the degradation of the spectral response and of the dark current characteristic upon irradiation. A shallow junction solar cell processed into a thin‐film device has the lowest sensitivity to electron radiation, showing an efficiency at the end of life equivalent to 82% of the beginning‐of‐life efficiency.

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Section: Introductionmentioning

confidence: 99%

Electron radiation–induced degradation of GaAs solar cells with different architectures

Gruginskie

Cappelluti

Bauhuis

et al. 2020

Progress in Photovoltaics

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“…For III‐V solar cells however, light‐trapping schemes based on simple wet etches that directly texture the semiconductor surface have not been reported. Typical strategies to incorporate light trapping in III‐V cells employ plasmonic scatterers, nanostructured window layers, and (dielectric) nanostructures at the rear or periodic gratings for (multi)resonant absorption . Despite the success of these methods in increasing the absorptance, they can typically be experimentally challenging, difficult to upscale or introduce substantial parasitic optical or electrical losses into the cells.…”

Section: Introductionmentioning

confidence: 99%

A facile light‐trapping approach for ultrathin GaAs solar cells using wet chemical etching

Eerden¹,

Bauhuis²,

Mulder³

et al. 2019

Progress in Photovoltaics

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Thinning down the absorber layer of GaAs solar cells can reduce their cost and improve their radiation hardness, which is important for space applications. However, the lighttrapping schemes necessary to achieve high absorptance in these cells can be experimentally challenging or introduce various parasitic losses. In this work, a facile light‐trapping approach based on wet chemical etching is demonstrated. The rear‐side contact layer of ultrathin GaAs solar cells is wet‐chemically textured in between local Ohmic contact points using an NaOH‐based etchant. The resulting contact layer morphology is characterized using atomic force microscopy and scanning electron miscroscopy. High broadband diffuse reflectance and haze factors are measured on bare and Ag‐coated textured contact layers. The textured contact layer is successfully integrated as a diffusive rear mirror in thin‐film solar cells comprising a 300‐nm GaAs absorber and Ag rear contact. Consistent increases in short‐circuit current density (JSC) of approximately 3 mA cm−2 (15%) are achieved in the textured cells, while the open‐circuit voltages and fill factors do not suffer from the textured rear mirror. The best cell achieves a JSC of 24.8 mA cm−2 and a power conversion efficiency of 21.4%. The textured rear mirror enhances outcoupling of luminescence at open circuit, leading to a strong increase in the external luminescent efficiency.

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“…Another promising approach is represented by III-V quantum dot solar cells (QDSCs), where QDs will increase the short circuit current density (Jsc) of the GaAs solar cell [12,13]. QDSCs are promising devices both for bandgap tuning in multijunction cells and for realizing intermediate band solar cells (IBSCs) [14].…”

Section: Introductionmentioning

confidence: 99%

“…As the simplest approach for improving the absorption, highly reflective planar back reflectors could effectively double the length of the optical path, increasing the J sc . This approach has been demonstrated for GaAs solar cells [18], GaInNAs solar cells [10], and QDSCs [13]. The length of the optical path can be increased even more with a back reflector grating that induce light diffraction, of which various approaches have been published [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

“…In particular, the gratings are designed for enhancing interband transitions of typical InAs/GaAs QDSCs in the wavelength range of 900 nm -1200 nm [13,24]. While this is sufficient for optimizing QDSCs working in the single-gap limit [13], the ideas presented in this work should be further developed to devise suitable strategies for the simultaneous enhancement of QD intersubband transitions, involving longer wavelengths [15,25]. In this study, different structures were simulated and fabricated for assessing diffraction efficiencies and their dependence on the design features.…”

Section: Introductionmentioning

confidence: 99%

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Comparison of metal/polymer back reflectors with half-sphere, blazed, and pyramid gratings for light trapping in III-V solar cells

Aho¹,

Guina²,

Elsehrawy³

et al. 2018

Opt. Express

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We report on the fabrication of diffraction gratings for application as back contact reflectors. The gratings are designed for thin-film solar cells incorporating absorbers with bandgap slightly lower than GaAs, i.e. InAs quantum dot or GaInNAs solar cells. Light trapping in the solar cells enables the increase of the absorption leading to higher short circuit current densities and higher efficiencies. We study metal/polymer back reflectors with half-sphere, blazed, and pyramid gratings, which were fabricated either by photolithography or by nanoimprint lithography. The gratings are compared in terms of the total and the specular reflectance, which determine their diffraction capabilities, i.e. the feature responsible for increasing the absorption. The pyramid grating showed the highest diffuse reflection of light compared to the half-sphere structure and the blazed grating. The diffraction efficiency measurements were in agreement with the numerical simulations. The validated model enables designing such metal/polymer back reflectors for other type of solar cells by refining the optimal dimensions of the gratings for different wavelength ranges.

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Light-trapping enhanced thin-film III-V quantum dot solar cells fabricated by epitaxial lift-off

Cited by 23 publications

References 53 publications

Electron radiation–induced degradation of GaAs solar cells with different architectures

Electron radiation–induced degradation of GaAs solar cells with different architectures

A facile light‐trapping approach for ultrathin GaAs solar cells using wet chemical etching

Comparison of metal/polymer back reflectors with half-sphere, blazed, and pyramid gratings for light trapping in III-V solar cells

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