Gallium arsenide solar cells grown at rates exceeding 300 µm h−1 by hydride vapor phase epitaxy

Metaferia, Wondwosen; Schulte, Kevin L.; Simon, John; Johnston, Steve; Ptak, Aaron J.

doi:10.1038/s41467-019-11341-3

Cited by 71 publications

(54 citation statements)

References 25 publications

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“…For example, while traditional 2T devices require highly-doped, transparent tunnel junctions and traditional 3T devices require highly-doped, transparent contact layers in the middle of the structure, the HBTSC requires neither (see Figure 1c). This, combined with the fact that quaternary or metamorphic layers are also not necessary (because of the exibility in E G choice inherent to 3T devices), makes the HBTSC an excellent candidate for the use of emerging materials or for the application of low-cost epitaxial techniques, such as high-throughput epitaxy 26,27 and the sequential growth of many device structures on a single substrate. 28 Different designs of HBTSCs including emerging low-cost materials, such as metal-halide perovskites or nanowires, have already been proposed.…”

Section: Main Textmentioning

confidence: 99%

GaInP/GaAs three-terminal heterojunction bipolar transistor solar cell

Zehender

Svatek

Steiner

et al. 2020

Preprint

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We demonstrate a novel multijunction architecture, the heterojunction bipolar transistor solar cell (HBTSC), which exhibits the performance of a double-junction solar cell in a more compact npn (or pnp) semiconductor structure. The HBTSC concept has the advantages of being a three-terminal device, such as low spectral sensitivity and high tolerance to non-optimal band gap energies, while it reduces the fabrication and operation complexity with respect to other multi-terminal devices because, for example, it can produce independent power extraction from the two junctions without the need for extra layers for their isolation or inter-connection. The top and bottom junctions in our proof-of-concept HBTSC prototype, which is made of epitaxial GaInP/GaAs, exhibit independent current-voltage characteristics under AM1.5G illumination, with respective open-circuit voltages of 1.33 and 0.95 V. The voltage difference between the two junctions is notable considering that they share a thin (< 600 nm) GaInP layer which contributes to the photogeneration of both junctions. This can be explained by a gradient in the minority carrier quasi-Fermi level within the base layer, which is compatible with a high fill factor. We also offer a technological solution for contacting the intermediate layer and study the effect of series resistance on the device performance. The HBTSC opens a new perspective in the understanding of multi-junction devices and it is an excellent candidate for the application of low-cost fabrication techniques, and for the implementation of III-V on silicon tandems with parallel/series interconnection for high energy yield.

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Section: Main Textmentioning

confidence: 99%

GaInP/GaAs three-terminal heterojunction bipolar transistor solar cell

Zehender

Svatek

Steiner

et al. 2020

Preprint

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“…These include efficient use of precursor materials, epitaxial growth rates in metalorganic vapor phase epitaxy (MOVPE) beyond 100 μm h À1 , or hydride vapor phase epitaxy. [6][7][8] There are two approaches to combine III-V and Si solar cells into a triple-junction device: Either by direct growth or layer transfer. Direct growth is attractive from the cost point of view because the cost associated with III-V substrates is avoided but very challenging due to the 4% lattice mismatch and difference in thermal expansion coefficients between Si and GaAs.…”

Section: Introductionmentioning

confidence: 99%

Two‐Terminal Direct Wafer‐Bonded GaInP/AlGaAs//Si Triple‐Junction Solar Cell with AM1.5g Efficiency of 34.1%

et al. 2020

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The terrestrial photovoltaic market is dominated by single‐junction silicon solar cell technology. However, there is a fundamental efficiency limit at 29.4%. This is overcome by multijunction devices. Recently, a GaInP/GaAs//Si wafer‐bonded triple‐junction two‐terminal device is presented with a 33.3% (AM1.5g) efficiency. Herein, it is analyzed how this device is improved to reach a conversion efficiency of 34.1%. By improving the current matching, an efficiency of 35% (two terminals, AM1.5g) is expected.

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“…Third, the trap densities measured in the perovskites are <10 11 cm −3 , also superior to that of GaAs (>0 14 cm −3 ). [ 57,58 ] A lower trap density is favorable for increasing the radiative recombination. Fourth, MAPbX 3 also shows a large hole mobility of 164 ± 25 cm 2 V −1 s −1 and electron mobility of 24.0 ± 4.1 cm 2 V −1 s −1 , [ 59 ] which are valuable for developing high brightness light‐emitting diodes (LEDs) with lower bias voltages.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, passivation of surface defects was also achieved with submicrometer perovskite structures. Finally, they achieved perovskite LEDs with a maximum EQE of 20.7%, which corresponds to an energy-conversion efficiency of 12%, close to that of the MA based perovskite >2 × 10 4 [53] 375 [55] <10 11 [57] 164 ± 25 [59] 24.0 ± 4.1 [59] GaAs 10 4 [54] <8 [56] >10 14 [58] 491.5 [60] 9400 [60] www.advopticalmat.de state of the art organic LEDs. [61] Recently, high efficiency red and near infrared perovskite LEDs with EQE up to 21.3% and 21.6% have also been reported.…”

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confidence: 98%

Stability of Perovskite Light Sources: Status and Challenges

Chen

Cui

et al. 2020

Advanced Optical Materials

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Stable perovskites light sources with long‐term stability are of great significance for future commercial applications. In this review, recent advances of the degradation models for perovskites and strategies for enhancing the stability of the corresponding light sources are summarized. Improving the stability and quality of perovskite materials is a common way for developing stable perovskite light sources. For strengthening the stability of perovskite light‐emitting diodes, approaches such as surface and interface engineering and employing more stable hole injection layers are effective. To enhance the stability of perovskite amplified spontaneous emission and lasers, methods such as protecting perovskites by materials with high intrinsic thermal conductivity and high stability, better thermal managements, and reducing the threshold carrier densities are useful. This work will be helpful for further prompting the performances, especially the stability of perovskite light sources in this fantastic field.

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Gallium arsenide solar cells grown at rates exceeding 300 µm h−1 by hydride vapor phase epitaxy

Cited by 71 publications

References 25 publications

GaInP/GaAs three-terminal heterojunction bipolar transistor solar cell

GaInP/GaAs three-terminal heterojunction bipolar transistor solar cell

Two‐Terminal Direct Wafer‐Bonded GaInP/AlGaAs//Si Triple‐Junction Solar Cell with AM1.5g Efficiency of 34.1%

Stability of Perovskite Light Sources: Status and Challenges

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