III-V Heteroepitaxy for Solar Energy Conversion

A special issue of Crystals (ISSN 2073-4352).

Deadline for manuscript submissions: closed (28 February 2019)

Special Issue Editor


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Guest Editor
Competence Center Emerging Technologies,
Fraunhofer Institute for Systems and Innovation Research ISI,
Breslauer Str. 48 | 76139 Karlsruhe | Germany
Interests: III-V semiconductors; epitaxy; in situ analysis; surface science; critical interfaces; solar energy; photoelectrochemistry; innovation systems; technology roadmapping

Special Issue Information

Dear Colleagues,

III-V devices have set efficiency records, in both photovoltaic and photoelectrochemical conversion of solar energy, for decades. The unrivalled technical merits are based on: (a) superior semiconductor properties; (b) advanced epitaxial material quality; and (c) facile heterostructure integration. The III-V material system dominates optoelectronic technologies—except for solar energy conversion, where the high cost still constrains commercial success in niche markets. Vast promises and critical bottlenecks associated with III-V materials in solar energy generation constitute a challenging context for the current Special Issue.

This Special Issue, on “III-V Heteroepitaxy for Solar Energy Conversion”, is intended to provide a unique international forum, aimed at exploring both technological perspectives and commercialization prospects of epitaxial III-V absorbers, with respect to future sustainable systems. Scientists working in a wide range of disciplines are invited to contribute to this Special Issue.

The keywords below broadly cover the general topics, framing a greater number of sub-topics that we have in mind. This volume, especially, is open to visionary and/or interdisciplinary work addressing advanced epitaxial devices or components for solar energy systems, or prospects for their widespread application. Subject areas of particular interest include:

  • Advanced solar absorber structures and concepts
  • Multi-junction photovoltaics and device implementation strategies
  • Efficient solar fuel generation and material durability
  • Structural characterization and in situ analysis
  • High-volume production and emerging growth techniques
  • Alternative substrates and substrate reuse
  • Sustainability and economic viability

Dr. Henning Döscher
Guest Editor

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Keywords

  • III-V semiconductors
  • Epitaxial growth
  • Photovoltaics
  • Solar fuel generation

 

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Published Papers (3 papers)

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Research

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9 pages, 1492 KiB  
Article
Optical Characterization and Photovoltaic Performance Evaluation of GaAs p-i-n Solar Cells with Various Metal Grid Spacings
by Jenq-Shinn Wu, Der-Yuh Lin, Yun-Guang Li, Hung-Pin Hsu, Ming-Cheng Kao and Hone-Zern Chen
Crystals 2019, 9(3), 170; https://doi.org/10.3390/cryst9030170 - 22 Mar 2019
Cited by 4 | Viewed by 2987
Abstract
GaAs p-i-n solar cells are studied using electroreflectance (ER) spectroscopy, light beam induced current (LBIC) mapping and photovoltaic characterization. Using ER measurements, the electric field across the pn junction of a wafer can be evaluated, showing 167 kV/cm and 275 kV/cm in the [...] Read more.
GaAs p-i-n solar cells are studied using electroreflectance (ER) spectroscopy, light beam induced current (LBIC) mapping and photovoltaic characterization. Using ER measurements, the electric field across the pn junction of a wafer can be evaluated, showing 167 kV/cm and 275 kV/cm in the built-in condition and at −3 V reverse bias, respectively. In order to understand the effect of the interval between metal grids on the device’s solar performance, we performed LBIC mapping and solar illumination on samples of different grid spacings. We found that the integrated photocurrent intensity of LBIC mapping shows a consistent trend with the solar performance of the devices with various metal grid spacings. For the wafer used in this study, the optimal grid spacing was found to be around 300 μm. Our results clearly show the importance of the metal grid pattern in achieving high-efficiency solar cells. Full article
(This article belongs to the Special Issue III-V Heteroepitaxy for Solar Energy Conversion)
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Review

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15 pages, 932 KiB  
Review
Tunnel Junctions for III-V Multijunction Solar Cells Review
by Peter Colter, Brandon Hagar and Salah Bedair
Crystals 2018, 8(12), 445; https://doi.org/10.3390/cryst8120445 - 28 Nov 2018
Cited by 38 | Viewed by 10281
Abstract
Tunnel Junctions, as addressed in this review, are conductive, optically transparent semiconductor layers used to join different semiconductor materials in order to increase overall device efficiency. The first monolithic multi-junction solar cell was grown in 1980 at NCSU and utilized an AlGaAs/AlGaAs tunnel [...] Read more.
Tunnel Junctions, as addressed in this review, are conductive, optically transparent semiconductor layers used to join different semiconductor materials in order to increase overall device efficiency. The first monolithic multi-junction solar cell was grown in 1980 at NCSU and utilized an AlGaAs/AlGaAs tunnel junction. In the last 4 decades both the development and analysis of tunnel junction structures and their application to multi-junction solar cells has resulted in significant performance gains. In this review we will first make note of significant studies of III-V tunnel junction materials and performance, then discuss their incorporation into cells and modeling of their characteristics. A Recent study implicating thermally activated compensation of highly doped semiconductors by native defects rather than dopant diffusion in tunnel junction thermal degradation will be discussed. AlGaAs/InGaP tunnel junctions, showing both high current capability and high transparency (high bandgap), are the current standard for space applications. Of significant note is a variant of this structure containing a quantum well interface showing the best performance to date. This has been studied by several groups and will be discussed at length in order to show a path to future improvements. Full article
(This article belongs to the Special Issue III-V Heteroepitaxy for Solar Energy Conversion)
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21 pages, 4910 KiB  
Review
GaAs Nanowires Grown by Catalyst Epitaxy for High Performance Photovoltaics
by Ying Wang, Xinyuan Zhou, Zaixing Yang, Fengyun Wang, Ning Han, Yunfa Chen and Johnny C. Ho
Crystals 2018, 8(9), 347; https://doi.org/10.3390/cryst8090347 - 29 Aug 2018
Cited by 8 | Viewed by 5179
Abstract
Photovoltaics (PVs) based on nanostructured III/V semiconductors can potentially reduce the material usage and increase the light-to-electricity conversion efficiency, which are anticipated to make a significant impact on the next-generation solar cells. In particular, GaAs nanowire (NW) is one of the most promising [...] Read more.
Photovoltaics (PVs) based on nanostructured III/V semiconductors can potentially reduce the material usage and increase the light-to-electricity conversion efficiency, which are anticipated to make a significant impact on the next-generation solar cells. In particular, GaAs nanowire (NW) is one of the most promising III/V nanomaterials for PVs due to its ideal bandgap and excellent light absorption efficiency. In order to achieve large-scale practical PV applications, further controllability in the NW growth and device fabrication is still needed for the efficiency improvement. This article reviews the recent development in GaAs NW-based PVs with an emphasis on cost-effectively synthesis of GaAs NWs, device design and corresponding performance measurement. We first discuss the available manipulated growth methods of GaAs NWs, such as the catalytic vapor-liquid-solid (VLS) and vapor-solid-solid (VSS) epitaxial growth, followed by the catalyst-controlled engineering process, and typical crystal structure and orientation of resulted NWs. The structure-property relationships are also discussed for achieving the optimal PV performance. At the same time, important device issues are as well summarized, including the light absorption, tunnel junctions and contact configuration. Towards the end, we survey the reported performance data and make some remarks on the challenges for current nanostructured PVs. These results not only lay the ground to considerably achieve the higher efficiencies in GaAs NW-based PVs but also open up great opportunities for the future low-cost smart solar energy harvesting devices. Full article
(This article belongs to the Special Issue III-V Heteroepitaxy for Solar Energy Conversion)
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