High Efficiency Nanostructured Iii V Photovoltaics For Solar Concentrator Application PDF Download

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High Efficiency Nanostructured III-V Photovoltaics for Solar Concentrator Application

High Efficiency Nanostructured III-V Photovoltaics for Solar Concentrator Application
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Release: 2012
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The High Efficiency Nanostructured III-V Photovoltaics for Solar Concentrators project seeks to provide new photovoltaic cells for Concentrator Photovoltaics (CPV) Systems with higher cell efficiency, more favorable temperature coefficients and less sensitivity to changes in spectral distribution. The main objective of this project is to provide high efficiency III-V solar cells that will reduce the overall cost per Watt for power generation using CPV systems. This work is focused both on a potential near term application, namely the use of indium arsenide (InAs) QDs to spectrally "tune" the middle (GaAs) cell of a SOA triple junction device to a more favorable effective bandgap, as well as the long term goal of demonstrating intermediate band solar cell effects. The QDs are confined within a high electric field i-region of a standard GaAs solar cell. The extended absorption spectrum (and thus enhanced short circuit current) of the QD solar cell results from the increase in the sub GaAs bandgap spectral response that is achievable as quantum dot layers are introduced into the i-region. We have grown InAs quantum dots by OMVPE technique and optimized the QD growth conditions. Arrays of up to 40 layers of strain balanced quantum dots have been experimentally demonstrated with good material quality, low residual stain and high PL intensity. Quantum dot enhanced solar cells were grown and tested under simulated one sun AM1.5 conditions. Concentrator solar cells have been grown and fabricated with 5-40 layers of QDs. Testing of these devices show the QD cells have improved efficiency compared to baseline devices without QDs. Device modeling and measurement of thermal properties were performed using Crosslight APSYS. Improvements in a triple junction solar cell with the insertion of QDs into the middle current limiting junction was shown to be as high as 29% under one sun illumination for a 10 layer stack QD enhanced triple junction solar cell. QD devices have strong potential for net gains in efficiency at high concentration.

Towards High Efficiency and Low Cost Nano-structured III-V Solar Cells

Towards High Efficiency and Low Cost Nano-structured III-V Solar Cells
Author: Gu Anjia
Publisher:
Total Pages:
Release: 2011
Genre:
ISBN:
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State-of-the-art III-V multijunction solar cells have achieved a record efficiency of 42%, the highest solar-electric conversion efficiency achieved by any technology. This has fueled great interest in the utility sector for large-scale deployment of solar cells. However, III-V solar cells have thus far proven too expensive for widespread terrestrial applications due to the combined cost of substrates, growth processes and materials. Here, we propose a novel III-V solar cell design based on the epitaxial growth of AlGaAs/GaAs on pre-patterned low-cost substrates to provide a path to cost-effective, large-scale deployment. This approach is based on our discovery that the surface kinetics of epitaxial growth by MBE is significantly altered when growing on three dimensional nanostructures instead of planar surfaces. Based on our exploratory results, we present the device design, electrical and optical simulation, and materials growth and device fabrication and characterization of core-shell nanostructured III-V solar cells. We use both bottom-up and top-down approaches to prepare the nanostructured templates in shape of nanowires and nanopyramids. Finite-difference time-domain (FDTD) and Rigorous Coupled Wave Analysis (RCWA) simulation show that the nanostructures have enhanced absorption and much wider incident acceptance angles than their planar counterpart, and outperform planar three-layer anti-reflective coatings. We first demonstrated high quality, single crystal III-V (GaAs and AlGaAs) polar material conformally epi grown on group IV (nanostructured Ge on Si substrate) nonpolar material via MBE and MOVPE (also known as MOCVD) with largely reduced anti-phase domains. We developed complete and mature routines to fabricate a working, single crystalline III-V solar cell on a nanostructured template. The I-V characterization of the fabricated nanostructured GaAs solar cell proves the concept and shows the great potential of making high-efficiency nano-structured III-V solar cells on low-cost substrates.

High-Efficiency Solar Cells

High-Efficiency Solar Cells
Author: Xiaodong Wang
Publisher: Springer Science & Business Media
Total Pages: 664
Release: 2013-11-01
Genre: Technology & Engineering
ISBN: 3319019880
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As part of the effort to increase the contribution of solar cells (photovoltaics) to our energy mix, this book addresses three main areas: making existing technology cheaper, promoting advanced technologies based on new architectural designs, and developing new materials to serve as light absorbers. Leading scientists throughout the world create a fundamental platform for knowledge sharing that combines the physics, materials, and device architectures of high-efficiency solar cells. While providing a comprehensive introduction to the field, the book highlights directions for further research, and is intended to stimulate readers’ interest in the development of novel materials and technologies for solar energy applications.

Nanostructures in III-V Solar Cells

Nanostructures in III-V Solar Cells
Author: Dong Liang
Publisher:
Total Pages:
Release: 2013
Genre:
ISBN:
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From the physics and materials viewpoint, III-V materials are ideal for highly efficient photovoltaic conversion. Their major limitations are cost and resource availability. As industrial planar III-V solar cells continue to set the all-time efficiency records, nanostructured III-V solar cells are now being investigated in academia with the goal to further improve the efficiency and lower the required materials volume and cost. However, most previously investigated nano-structured solar cells suffer from low efficiencies. In this dissertation, I first present optical enhancement in nanopyramid III-V ultra-thin films which can potentially reduce the required materials by one order of magnitude. I then demonstrate significant efficiency improvement in GaAs solar cell. Especially, with an AlGaAs nanocone window layer, a 17%-efficiency nanostructured single-junction solar cell is obtained. The first part of my dissertation focuses on optical engineering and absorption improvement in nanopyramid GaAs ultra-thin film. I demonstrate a double-sided nanopyramid GaAs film that is only 160 nm thick, laminated in a flexible transparent superstrate. Without additional antireflection coatings, this nanopyramid film absorbs over 80% more photons than a planar counterpart with equal thickness at normal incidence and is equivalent to a 1um thick film. At large incident angles, this enhancement can be even greater. With similar light trapping design, III-V solar cell film thickness can be potentially reduced from 3-4 um to 200-300 nm, which could significantly reduce III-V cell cost. The second part of my dissertation focuses on efficiency improvement in III-V nanostructured solar cells. First, GaAs solar cell efficiency enhancement using ZnO nanoparticle antireflection coating is briefly demonstrated. I then demonstrate our work on nanostructured p-n junction solar cells and discuss the challenges for nanostructured solar cell. After this, I propose a nanowindow solar cell design that can overcome these challenges by enhancing both optical and electrical properties. A nanowindow solar cell using a nanocone AlGaAs window layer, a GaAs junction and mesa grid contact is demonstrated with a high energy conversion efficiency of 17.0% and high open circuit voltage of 0.982 V.

High Efficiency III/V Thin Film Solar Cells

High Efficiency III/V Thin Film Solar Cells
Author: Xiaohan Li (Ph. D.)
Publisher:
Total Pages: 168
Release: 2015
Genre:
ISBN:
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Photon management via submicron and subwavelength nanostructures has been extensively studied over the last decade, and has become one of the most important approaches of boosting the energy conversion efficiency for thin-film photovoltaic devices. The incorporation of low dimensional nanostructures, such as GaAs/InGaAs quantum wells, into typical GaAs single-junction cells will extend the cell absorption further into the sub-GaAs bandgap region but usually results in reduced cell open-circuit voltage. As a consequence, various bandgap engineering techniques for improving the energy conversion efficiency for quantum well solar cells have been reported. This dissertation will describe studies of light trapping in multiple GaAs/InGaAs quantum well solar cells via nanostructured front side dielectric coating and back side metal/dielectric contacts, photovoltaic performance enhancement for bulk and flexible thin-film GaAs solar cells through subwavelength nanostructured antireflection coating, and bandgap engineering techniques for GaAs/InGaAs multiple quantum well solar cells. In the study of nanostructured dielectric antireflection coatings, a 5.8% increase in short-circuit current density is observed for the GaAs/In0.3Ga0.7As multiple quantum well cell coated with TiO2 nanostructured coating compared to the cell coated with conventional Si3N4 single-layer antireflection coating even in the presence of high surface recombination. Numerical simulation shows that as high as 13% increase in short-circuit current density can be achieved without surface recombination. In the study of GaAs/In0.3Ga0.7As multiple quantum well solar cells integrated with nanostructured back side metal/dielectric contacts, as high as 2.9% per quantum well external quantum efficiency is achieved, significantly surpassing the 1% per quantum well external quantum efficiency typically observed in quantum well solar cells. In both studies, two major mechanisms contributing to the increased longer wavelength quantum well absorption have been elucidated: Fabry-Perot resonances and scattering into guided optical modes. In application of subwavelength-scale optical nanostructures on bulk and flexible epitaxial lift-off GaAs solar cells for broadband, omnidirectional improvement of photovoltaic performance, 1.1× increase in short-circuit current density is observed for the bulk GaAs cell fully integrated with optical nanostructures compared to the unpatterned cell (1.09× increase in short-circuit current density for flexible epitaxial lift-off GaAs cell) at normal incidence, while 1.67× increase in short-circuit current density is observed (1.52× increase in short-circuit current density is observed for flexible epitaxial lift-off GaAs cell) at 80° angle of incidence. In the study of bandgap engineering strategies for improving the photovoltaic performance for GaAs/InGaAs multiple quantum well solar cells, a quantum well solar cell with graded quantum well depths, which has an average 18% indium concentration in quantum wells, is shown to yield improvements in both open-circuit voltage and short-circuit current density compared to a GaAs/In0.18Ga0.82As quantum well solar cell with constant quantum well depths across the intrinsic region. The results of this study suggest that such an approach can also be implemented in quantum well solar cells with more complex quantum well structures, such as ternary or quaternary quantum wells, where the conduction and valence band offsets of each quantum well can be simultaneously engineered.

Nanostructured Materials for Type III Photovoltaics

Nanostructured Materials for Type III Photovoltaics
Author: Peter Skabara
Publisher: Royal Society of Chemistry
Total Pages: 532
Release: 2017-11-08
Genre: Science
ISBN: 178801250X
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Materials for type III solar cells have branched into a series of generic groups. These include organic ‘small molecule’ and polymer conjugated structures, fullerenes, quantum dots, copper indium gallium selenide nanocrystal films, dyes/TiO2 for Grätzel cells, hybrid organic/inorganic composites and perovskites. Whilst the power conversion efficiencies of organic solar cells are modest compared to other type III photovoltaic materials, plastic semiconductors provide a cheap route to manufacture through solution processing and offer flexible devices. However, other types of materials are proving to be compatible with this type of processing whilst providing higher device efficiencies. As a result, the field is experiencing healthy competition between technologies that is pushing progress at a fast rate. In particular, perovskite solar cells have emerged very recently as a highly disruptive technology with power conversion efficiencies now over 20%. Perovskite cells, however, still have to address stability and environmental issues. With such a diverse range of materials, it is timely to capture the different technologies into a single volume of work. This book will give a collective insight into the different roles that nanostructured materials play in type III solar cells. This will be an essential text for those working with any of the devices highlighted above, providing a fundamental understanding and appreciation of the potential and challenges associated with each of these technologies.

Nanostructured And Photoelectrochemical Systems For Solar Photon Conversion

Nanostructured And Photoelectrochemical Systems For Solar Photon Conversion
Author: Mary D Archer
Publisher: World Scientific
Total Pages: 781
Release: 2008-08-04
Genre: Science
ISBN: 1783261536
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In this book, expert authors describe advanced solar photon conversion approaches that promise highly efficient photovoltaic and photoelectrochemical cells with sophisticated architectures on the one hand, and plastic photovoltaic coatings that are inexpensive enough to be disposable on the other. Their leitmotifs include light-induced exciton generation, junction architectures that lead to efficient exciton dissociation, and charge collection by percolation through mesoscale phases. Photocatalysis is closely related to photoelectrochemistry, and the fundamentals of both disciplines are covered in this volume./a

Nanostructured Materials for Next-Generation Energy Storage and Conversion

Nanostructured Materials for Next-Generation Energy Storage and Conversion
Author: Tulay Aygan Atesin
Publisher: Springer Nature
Total Pages: 540
Release: 2019-11-15
Genre: Technology & Engineering
ISBN: 366259594X
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Nanostructured Materials for Next-Generation Energy Storage and Conversion: Photovoltaic and Solar Energy, is volume 4 of a 4-volume series on sustainable energy. Photovoltaic and Solar Energy while being a comprehensive reference work, is written with minimal jargon related to various aspects of solar energy and energy policies. It is authored by leading experts in the field, and lays out theory, practice, and simulation studies related to solar energy and allied applications including policy, economic and technological challenges. Topics covered include: introduction to solar energy, fundamentals of solar radiation, heat transfer, thermal collection and conversion, solar economy, heating, cooling, dehumidification systems, power and process heat, solar power conversion, policy and applications pertinent to solar energy as viable alternatives to fossil fuels. The aim of the book is to present all the information necessary for the design and analysis of solar energy systems for engineers, material scientists, economics, policy analysts, graduate students, senior undergraduates, solar energy practitioner, as well as policy or lawmakers in the field of energy policy, international energy trade, and libraries which house technical handbooks related to energy, energy policy and applications.

Concentrator Photovoltaics

Concentrator Photovoltaics
Author: Antonio Luque López
Publisher: Springer
Total Pages: 348
Release: 2007-08-17
Genre: Technology & Engineering
ISBN: 354068798X
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This book gives an overview of all components, e.g. cells, concentrators, modules and systems, for systems of concentrator photovoltaics. It is an application-oriented book. The authors report on significant results related to design, technology, and applications, and they also cover the fundamental physics and market considerations.

Nanostructured Solar Cells

Nanostructured Solar Cells
Author: Narottam Das
Publisher: BoD – Books on Demand
Total Pages: 316
Release: 2017-02-22
Genre: Technology & Engineering
ISBN: 953512935X
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Nanostructured solar cells are very important in renewable energy sector as well as in environmental aspects, because it is environment friendly. The nano-grating structures (such as triangular or conical shaped) have a gradual change in refractive index which acts as a multilayer antireflective coating that is leading to reduced light reflection losses over broadband ranges of wavelength and angle of incidence. There are different types of losses in solar cells that always reduce the conversion efficiency, but the light reflection loss is the most important factor that decreases the conversion efficiency of solar cells significantly. The antireflective coating is an optical coating which is applied to the surface of lenses or any optical devices to reduce the light reflection losses. This coating assists for the light trapping capturing capacity or improves the efficiency of optical devices, such as lenses or solar cells. Hence, the multilayer antireflective coatings can reduce the light reflection losses and increases the conversion efficiency of nanostructured solar cells.