Author : 林立彥
Publisher :
Page : pages
File Size : 13,60 MB
Release : 2013
Category :
ISBN :
Author :
Publisher :
Page : pages
File Size : 50,48 MB
Release : 2014
Category :
ISBN :
Author : Paul Barber Armstrong
Publisher :
Page : 232 pages
File Size : 23,78 MB
Release : 2010
Category :
ISBN :
The harvesting of solar energy using photovoltaics has the potential to provide a significant portion of the world's energy. For this to happen, the cost per watt of power produced from photovoltaics must decrease. Excitonic solar cells, including organic solar cells and dye-sensitized solar cells, have the potential to provide the necessary cost savings. However, power conversion efficiencies must be improved before these devices can become practical. This dissertation describes the implementation of several strategies to improve the efficiency of organic polymer and dye-sensitized solar cells. Chapter 1 provides an introduction to current research on excitonic solar cells with a focus on organic polymer and dye-sensitized cells. The detailed mechanisms of photocurrent generation in each type of cell are discussed, and the factors that determine efficiencies are outlined. In addition, an overview of the progress over the last decade in research on polymer photovoltaics is given. Finally, the future prospects for achieving high efficiency devices are described. Chapter 2 details a strategy for controlling the morphology of photovoltaic blends of conjugated polymers and small molecule perylene diimide dyes. Blends of these two materials are subject to excessive phase separation that decreases photovoltaic performance. The development of compatibilizers that alleviate this phase separation is described. A diblock copolymer of poly(3-hexylthiophene) (P3HT) and a perylene diimide (PDI) side chain polymer is an effective compatibilizer. Addition of this material to blends of P3HT and PDI suppresses the formation of micron-sized crystals and results in a 50% improvement in solar cell efficiency. The synthesis of a diblock copolymer of poly(3-(4-octylphenyl)thiophene) and the PDI side chain polymer is also described. This material functions as a compatibilizer, but does not allow for improved photovoltaic efficiency. Chapter 3 describes the synthesis and characterization of a low bandgap conjugated polymer with thermally removable solubilizing groups. Following solution-based deposition of thin films of this polymer, heat can induce the cleavage and evaporation of the alkyl solubilizing chains, resulting in an insoluble film. The optical properties change considerably during this process: the bandgap decreases, and the absorption coefficient increases dramatically. These properties were exploited to fabricate bilayers of the low bandgap material and a highly fluorescent commercial polymer. Fluorescence resonance energy transfer from the fluorescent material to the low bandgap polymer is efficient over 30 nm. Such a scheme could be utilized to overcome the exciton diffusion bottleneck in layered polymer solar cells. In chapter 4, the synthesis of novel n-type polymers based on PDI monomers is described. With appropriate substitution of alkyl chains, highly rigid perylene benzimidazole ladder polymers can be made soluble in common organic solvents. These materials have exceptionally low-lying LUMOs and possess unusual fluorescence properties. Fully planar perylene ethynylene polymers are also synthesized and characterized. Despite their planarity, data from absorbance and fluorescence spectra suggest that the PDI units in these polymers are poorly coupled electronically. X-Ray diffraction shows that the [pi]-stacking distance varies in these materials depending on the nature of the solubilizing groups and can be decreased through solvent annealing. Chapter 5 describes how light harvesting can be improved in dye-sensitized solar cells by adding a second dye that transfers energy to the primary sensitizing dye. In liquid cells, incorporation of a PDI dye in the liquid electrolyte solution results in a 28% improvement in power conversion efficiency. Energy transfer is at least 50% efficient despite significant quenching of the perylene dye's fluorescence by the iodide redox couple. Efforts to employ energy transfer in solid-state dye-sensitized solar cells are also described. This is more challenging because the solid-state hole transporter is an excellent quencher of fluorescent dyes. However, it is shown that this quenching can be prevented by self-assembling dyes such as fluorescein 548 into a poly(propyleneimine) dendrimer. Unfortunately, processing conditions that allow the dendrimer/dye conjugates to penetrate the pores of the cell's titania films have not yet been found.
Author : Bridget Diane Carsten
Publisher :
Page : 322 pages
File Size : 40,11 MB
Release : 2012
Category :
ISBN : 9781267437327
The need for sustainable alternatives to fossil fuels is dire. Organic solar cells present a cost-effective, sustainable alternative to their inorganic counterparts, using earth abundant carbon-based semiconducting materials. Herein, the design criteria for novel organic semiconducting polymers exhibiting the photovoltaic effect are examined. Novel donor and acceptor materials were designed for use in bulk heterojunction organic photovoltaic devices. New materials based on benzodithiophene and thienothiophene comonomers (the PBB series of polymers) were synthesized showing power conversion efficiencies as high as 2.04%. Further examination of the PBB series of polymers, namely PBB3, revealed a dipolar effect on charge separation in this polymer. The dipolar effect revealed new design principles which were utilized in the design of the PBIT polymer based on the novel dipyrrololbenzothiadiazole (DPBT) moiety, which employed a strategy to increase the magnitude of the dipole moment of the polymer backbone. Similarly, the PBTZ polymer series was designed to increase the net dipole moment, incorporating the dithiazolopyrrolopyrrole monomer. The PBTZ series revealed the importance of the change in polarity of the excited state over the ground state dipole moment in determining the efficiency of the polymer through theoretical predictions. The study of bulk heterojunction organic photovoltaics is dominated by incorporation of soluble fullerene derivatives as electron-deficient acceptors. Herein, the design, synthesis and testing of non-fullerene small-molecule and polymers as n-type acceptor units is reported.
Author : Adarsh Kumar Pandey
Publisher : Academic Press
Page : 259 pages
File Size : 50,48 MB
Release : 2021-10-23
Category : Science
ISBN : 0128182075
Dye-Sensitized Solar Cells: Emerging Trends and Advanced Applications is highly focused on addressing all aspects of dye sensitized solar cell technology. In this book, the authors present systematic analysis and working principles and detailed studies of individual components, manufacturing methods, software assisted design surrounding the technology market, commercialization potential, and performance evaluations and detailed fabrication methods and parameters. As there is no specific book which could encircle all the aspects of dye sensitized solar cells from its very basic working principles to advanced approached to improve it efficiency, this book fills that gap. Providing a comprehensive study on dye sensitized solar cells, this reference covers basic working principles to advanced approaches in improving efficiency as well as thermodynamic and kinetic studies. It will be ideal for advanced stage researchers and engineers looking to get a grip on DSSC technology. Provides a compilation of all-important principles and advanced research in the field of dye sensitized solar cells Specifies constituents of each DSSC, from basic to advanced level Details advances in fabrication and software assisted design of DSSC
Author : Srikanth Revoju
Publisher :
Page : pages
File Size : 26,22 MB
Release : 2018
Category :
ISBN : 9789176018354
Author : Swee Ching Tan
Publisher : CRC Press
Page : 255 pages
File Size : 15,76 MB
Release : 2018-09-03
Category : Medical
ISBN : 1498724906
Ever since the discovery of the photoelectric effect, researchers have been trying to improve the efficiency of converting sunlight into electricity through photovoltaic devices. Photosynthetic organisms provide clues for harvesting sunlight and storing the energy in chemical forms. This book offers a concise overview of the fundamental concepts of photosynthesis and the emerging photovoltaic technologies, casting light on the symbiotic relation between these spheres of science. Although there are many books about the fundamentals of photosynthesis and the various aspects of the photosynthetic processes, this is the first volume to focus on the prospects of studying the photosynthetic proteins, understanding and applying their properties to design prospective solar energy conversion devices that are sustainable and efficient. All in all, the book aims to bring together the present know-how on organic photovoltaics and dye-sensitized solar cells with that of the emerging bio-photovoltaics and the underlying physics of photosynthesis to foster a more eclectic research that would converge towards a sustainable energy technology for the future. The book mainly serves as a bridge to connect biochemists, who study photosynthetic proteins, and physicists and engineers who design and develop photovoltaic devices. Scientists, engineers and students in the fields of photosynthetic research and solar energy research can use this book as a ready reference. Key selling features: Covers both methods and bio-based materials needed to build bio-based photovoltaics Focuses on both techniques and applications Summarizes the advantages and limitations of various techniques Contributors from multiple disciplines integrate the knowledge of photosynthetic proteins and the physics/engineering of photovoltaic devices. Includes adaptive designs and techniques used in other types of solar cells to for the design of protein-based PVs
Author : Yuhang Liu
Publisher :
Page : 133 pages
File Size : 44,55 MB
Release : 2016
Category : Organic compounds
ISBN :
Author : Songyuan Dai
Publisher : Walter de Gruyter GmbH & Co KG
Page : 706 pages
File Size : 48,45 MB
Release : 2022-07-05
Category : Technology & Engineering
ISBN : 311038373X
The operation of everything in the universe needs a special „material“-energy. The earth is no exception. There are many kinds of energy sources on earth. But where does the earth‘s energy come from? The answer is that everything grows under the sun. Developing renewable energy is of strategic importance to achieve sustainable energy supply. Simulating natural photosynthesis is the ultimate goal of effi cient solar energy conversion. Photovoltaic technology has been widely used in industry and will be one of the major energy sources in the future. Developing new materials and structures, the photoelectric conversion effi ciency of solar cells will be improved day by day, and solar cells will attract more and more attention. This book presents principles of solar photovoltaic conversion, and introduces the physical and chemical processes involved. Mechanisms which affect solar cell performance are also discussed.
Author : Jacques Lalevée
Publisher : John Wiley & Sons
Page : 447 pages
File Size : 33,80 MB
Release : 2015-05-04
Category : Technology & Engineering
ISBN : 1119006872
The design and development of dyes and chromophores have recently attracted much attention in various research fields such as materials, radiation curing, (laser) imaging, optics, medicine, microelectronics, nanotechnology, etc.. In this book, the recent research for the use of dyes and chromophores in polymer science is presented. The interaction of the visible light with the dyes or the selected chromophores is particularly important in different fields (e.g. for photovoltaic, display applications (LED ...), laser imaging or laser direct writing, green chemistry with sunlight induced photopolymerization etc ...). This book gives an overview of the dyes and chromophores for all the important fields.
