GaAs photovoltaics and optoelectronics using releasable multilayer epitaxial assemblies

Yoon, Jongseung; Jo, Sungjin; Chun, Ik Su; Jung, Inhwa; Kim, Hoon Sik; Meitl, Matthew A.; Menard, Etienne; Li, Xiuling; Coleman, J. J.; Paik, Ungyu; Rogers, John A.

doi:10.1038/nature09054

Cited by 546 publications

(503 citation statements)

References 29 publications

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“…Disadvantages, compared with non-concentrating PV, arise from complexity associated with the optics and trackers, challenges in module assembly, difficulties in thermal management and inefficiencies in the capture of diffuse light. Recently developed microscale compound semiconductor multijunction cells, miniaturized optics and advanced manufacturing approaches address many of these issues 6 . Even these systems do not, however, function effectively in geographic locations where levels of direct normal irradiance are low, or in applications that demand mechanically flexible modules.…”

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confidence: 99%

Flexible concentrator photovoltaics based on microscale silicon solar cells embedded in luminescent waveguides

et al. 2011

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unconventional methods to exploit monocrystalline silicon and other established materials in photovoltaic (PV) systems can create new engineering opportunities, device capabilities and cost structures. Here we show a type of composite luminescent concentrator PV system that embeds large scale, interconnected arrays of microscale silicon solar cells in thin matrix layers doped with luminophores. Photons that strike cells directly generate power in the usual manner; those incident on the matrix launch wavelength-downconverted photons that reflect and waveguide into the sides and bottom surfaces of the cells to increase further their power output, by more than 300% in examples reported here. unlike conventional luminescent photovoltaics, this unusual design can be implemented in ultrathin, mechanically bendable formats. Detailed studies of design considerations and fabrication aspects for such devices, using both experimental and computational approaches, provide quantitative descriptions of the underlying materials science and optics.

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confidence: 99%

Flexible concentrator photovoltaics based on microscale silicon solar cells embedded in luminescent waveguides

et al. 2011

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“…4,5 For device applications, the growth of amorphous inorganic semiconductors 6,7 and organic thin films 8 on amorphous substrates has widely been studied. However, the devices based on single-crystalline compound semiconductors such as GaN show much higher efficiencies, reliability and long-term stability.…”

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confidence: 99%

High-quality GaN films grown on chemical vapor-deposited graphene films

et al. 2012

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We report the growth of high-quality GaN films on large-size graphene films for visible light-emitting diodes (LEDs). The graphene films were synthesized by chemical vapor deposition and then transferred onto amorphous silica (SiO 2 ) substrates that do not have an epitaxial relationship with GaN. Before growing the high-quality GaN thin films, ZnO nanowalls were grown on the graphene films as an intermediate layer. The structural and optical characteristics of the GaN films were investigated, and the films exhibited stimulated emission even at room temperature, a highly c-axis-oriented crystal structure, and a preferred in-plane orientation. Visible LEDs that emitted strong electroluminescence under room illumination were fabricated using the GaN thin films.

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“…This device demonstrated that the attainment of high efficiencies at 1000 suns and above is a reachable and realistic target. However, despite this excellent result it is clear that a dualjunction solar cell −though having interesting applications in approaches that aim substrate reuse, need substrate removal [4] or spectral splitting− has a limited efficiency potential when compared to state-of-the-art triple-junction solar cells. Accordingly, this methodology for UHCPV design is being applied to the development of lattice matched GaInP/GaInAs/Ge triple-junction devices, with the goal of achieving efficiencies in excess of 40% at 1000 suns and above.…”

Section: A From Dual-junction To Triple Junctionmentioning

confidence: 98%

Triple-junction solar cells for ultra-high concentrator applications

Barrigón

García‐Tabarés

García

et al. 2011

Proceedings of the 8th Spanish Conference on Electron Devices, CDE'2011

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Abstract-After the successful implementation of a record performing dual-junction solar cell at ultra high concentration, in this paper we present the transition to a triple-junction device. The semiconductor structure of the solar cells is presented and the main changes in respect to a dual-junction design are briefly discussed. Cross-sectional TEM analysis of samples confirms that the quality of the triple-junction structures grown by MOVPE is good, revealing no trace of antiphase disorder, and showing flat, sharp and clear interfaces between the layers. Triple-junction solar cells manufactured on these structures have shown a peak efficiency of 36.2% at 700X, maintaining the efficiency over 35% from 300 to 1200 suns. With some changes in the structure and a fine tuning of its processing, efficiencies close to 40% at 1000 suns are envisaged.

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GaAs photovoltaics and optoelectronics using releasable multilayer epitaxial assemblies

Cited by 546 publications

References 29 publications

Flexible concentrator photovoltaics based on microscale silicon solar cells embedded in luminescent waveguides

Flexible concentrator photovoltaics based on microscale silicon solar cells embedded in luminescent waveguides

High-quality GaN films grown on chemical vapor-deposited graphene films

Triple-junction solar cells for ultra-high concentrator applications

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