Control of In Surface Segregation and Inter-Diffusion in GaAs on InGaP Grown by Metal–Organic Vapor Phase Epitaxy

Fukushima, Yasuyuki; Nakano, Takayuki; Nakano, Yoshiaki; Shimogaki, Yukihiro

doi:10.1143/jjap.51.055601

Cited by 2 publications

(1 citation statement)

References 35 publications

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“…Therefore, a shallow junction solar cell processed into a thin‐film geometry is found to be the best structure for space applications. The MOCVD growth of hetero‐interfaces such as GaAs/AlInP and GaAs/InGaP has been shown to be a challenge in the past . A meticulous control of chemical composition, material inter‐diffusion and surface segregation is necessary in order to prevent the formation of mixed compounds that reduce the abruptness of the interfaces.…”

Section: Resultsmentioning

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: Resultsmentioning

confidence: 99%

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

Gruginskie

Cappelluti

Bauhuis

et al. 2020

Progress in Photovoltaics

View full text Add to dashboard Cite

show abstract

Limiting mechanisms for photon recycling in thin‐film GaAs solar cells

Gruginskie

Cappelluti

Bauhuis

et al. 2020

Progress in Photovoltaics

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Photon recycling mechanisms in single junction thin‐film GaAs solar cells are evaluated in this study. Modelling supported by experimentally obtained results is used in order to correlate the reflectance of the cell's rear layers, the photon recycling probability, and the solar cell performance. Solar cells with different top and bottom metallization configurations are produced, and their performance is analyzed from the optical and electrical point of view. It is shown that the photon recycling probability increases with the rear mirror reflectance and solar cell thickness, which results in the increase of the devices open circuit voltage. However, the front grid coverage, usually disregarded in rear mirror focused studies, strongly reduces the photon recycling probability. Furthermore, perimeter and interface recombination hinder the internal radiative efficiency of the solar cells, preventing further increase of the devices' open circuit voltage as a result of improvements of the rear mirror reflectivity. In order to exploit the significant benefit of increased photon recycling probability to the solar cell performance, these limiting mechanisms need to be properly addressed.

show abstract

Control of In Surface Segregation and Inter-Diffusion in GaAs on InGaP Grown by Metal–Organic Vapor Phase Epitaxy

Cited by 2 publications

References 35 publications

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

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

Limiting mechanisms for photon recycling in thin‐film GaAs solar cells

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