Open Access
Multijunction solar cell technologies - high efficiency, radiation resistance, and concentrator applications
Tatsuya Takamoto,Takaaki Agui,K. Kamimura,M. Kaneiwa +3 more
- Vol. 1, pp 581-586
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TLDR
In this article, the conversion efficiency of InGaP/(In)GaAs/Ge-based multijunction solar cells has been improved up to 29-30% and 31-32% by technologies, such as double-hetero wide band-gap tunnel junctions, combination with Ge bottom cell with the In-GaP first layer, and precise lattice-matching to Ge substrate by adding 1% indium to the conventional GaAs lattice match structure.Abstract:
The conversion efficiency of InGaP/(In)GaAs/Ge-based multijunction solar cells has been improved up to 29-30% (AM0) and 31-32% (AM1.5 G) by technologies, such as double-hetero wide band-gap tunnel junctions, combination with Ge bottom cell with the InGaP first layer, and precise lattice-matching to Ge substrate by adding 1% indium to the conventional GaAs lattice-match structure. Employing a 1.96 eV AlInGaP top cell should improve efficiency further. For space use, radiation resistance has been improved by technologies such as introducing of an electric field in the base layer of the lowest-resistance middle cell, and EOL current matching of sub-cells to the highest-resistance top cell. A grid structure has been designed for concentrator applications in order to reduce the energy loss due to series resistance, and 36% (AM1.5 G, 100-500 suns) efficiency has been demonstrated.read more
Citations
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Journal ArticleDOI
Multi-junction III-V solar cells: current status and future potential
TL;DR: In this paper, a 3-junction InGaP/InGaAs/Ge concentrator solar cell with an efficiency of 37.4% (AM1.5G, 200-suns) has been fabricated.
Journal ArticleDOI
Novel materials for high-efficiency III-V multi-junction solar cells
Masafumi Yamaguchi,Kenichi Nishimura,Takuo Sasaki,Hidetoshi Suzuki,Kouji Arafune,Nobuaki Kojima,Yoshio Ohsita,Yoshitaka Okada,Akio Yamamoto,Tatsuya Takamoto,Kenji Araki +10 more
TL;DR: In this paper, a wide bandgap InGaP double hetero structure tunnel junction for sub-cell interconnection, InGaAs middle cell lattice-matched to Ge substrate, and InGeP-Ge heteroface structure bottom cell were developed.
Journal ArticleDOI
Numerical simulation of tunnel diodes for multi‐junction solar cells
TL;DR: In this paper, the authors presented a two-dimensional model of a III-V multi-junction solar cell including the numerical model of the investigated Esaki tunnel diode.
Proceedings ArticleDOI
Numerical simulation of tunnel diodes and multi-junction solar cells
TL;DR: In this article, numerical simulations of an isolated III-V Esaki tunnel diode and of a dual-junction solar cell are presented with a tunnel model, which takes into account the full non-locality of the tunneling process.
Journal ArticleDOI
$I$ – $V$ Characterization of Tunnel Diodes and Multijunction Solar Cells
Wolfgang Guter,Andreas W. Bett +1 more
TL;DR: In this article, the authors discuss common difficulties in measuring tunnel diodes and sets a special focus on devices consisting of tunnel dodes and solar cells, such as multijunction solar cells.