Interface Engineering in Solid-state Dye-sensitized Solar Cells PDF Download
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Author: Jessica Krüger
Publisher:
ISBN:
Category :
Languages : en
Pages : 128
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Author: Jessica Krüger
Publisher:
ISBN:
Category :
Languages : en
Pages : 128
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Author: Thomas P. Brennan
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
The increasing demand for energy as standards of living and population sizes rise across the globe motivates the development of scalable resources to meet the forecasted doubling of energy consumption. This challenge is further compounded by the need to reduce the CO2 emissions associated with our current level of energy consumption in order to stave off costly changes in the global climate. Solar energy promises renewable, carbon-free energy and a resource that is orders of magnitude larger than alternative sources. Capturing this solar energy with photovoltaic devices has become an increasingly economical means of energy production, but further development is needed to make solar energy conversion inexpensive and ubiquitous. One particular class of photovoltaics--the dye-sensitized solar cell (DSSC)--is especially appealing because it can be constructed with abundant, inexpensive materials and be engineered in a modular fashion for a wide array of product applications. Challenges remain, however, in order to make DSSCs more efficient, more economical, and more practical. The DSSC architecture is quite different than traditional--i.e. silicon and thin film inorganic--photovoltaics in that light harvesting and charge collection are decoupled. This is achieved by depositing a thin nanometer-scale layer of light-absorbing dye molecules atop a high surface area nanostructured TiO2 anode. The consequence of this architecture, however, is an abundance of interfacial area at which deleterious charge recombination processes can occur. Further improvements in DSSC performance therefore require a thorough understanding of and high control over the dual-interface that exists between the dye layer and the electron-conducting anode and the dye layer and the hole-transporting material (HTM). In the first part of this work we describe the application of thin, sub-nanometer insulating metal oxide layers grown by atomic layer deposition (ALD) to the TiO2 anode for the purpose of slowing down the undesirable back-recombination of electrons injected into TiO2 by the light-absorbing dye molecules. We use the well-characterized insulator Al2O3 as a recombination barrier material and perform a comprehensive study of different parameters that impact how such barriers change device performance. In a solid-state DSSC we demonstrate the importance of the dye chemical structure and the anode fabrication process in dictating whether or not improvements achieved through the recombination suppression outweigh device current losses that result from the insertion of an insulating layer. We apply these lessons to a new barrier layer material, In2O3, that unlike Al2O3 has not been previously well-characterized but is less-insulating and can be grown at an extremely low growth rate, providing excellent control over the competing consequences of barrier layers. With In2O3 we are able to demonstrate some of the highest ever reported open-circuit voltages for this class of DSSC and we observe an unexpected change in behavior as the In2O3 barriers reach a certain thickness. In our third barrier layer study, we achieve a near-doubling in efficiency when Al2O3 is applied to a quantum dot-sensitized solar cell, a close analogue of the DSSC, wherein recombination more severely limits device performance. In the second part of this work, we combine experimental and computational techniques to study the dye/anode interface and the orientation of dye molecules adsorbed on a TiO2 surface. Near-edge X-ray absorption fine structure (NEXAFS) spectroscopy is used to measure the angles of individual bonds and in turn deduce the full geometry of adsorbed dye molecules. This result is compared to computational simulations using density functional theory-molecular dynamics (DFT-MD) of the same dye/TiO2 system. Our results show remarkable correspondence between the experimental and computational approaches and signify important consequences for understanding the dye/anode interface in DSSCs as well as adsorbate/substrate studies more generally.
Author: Masoud Soroush
Publisher: Academic Press
ISBN: 0128145420
Category : Science
Languages : en
Pages : 470
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Book Description
Dye-Sensitized Solar Cells: Mathematical Modelling and Materials Design and Optimization presents the latest information as edited from leaders in the field. It covers advances in DSSC design, fabrication and mathematical modelling and optimization, providing a comprehensive coverage of various DSSC advances that includes different system scales, from electronic to macroscopic level, and a consolidation of the results with fundamentals. The book is extremely useful as a monograph for graduate students and researchers, but is also a comprehensive, general reference on state-of-the-art techniques in modelling, optimization and design of DSSCs. Includes chapter contributions from worldwide leaders in the field Offers first-principles of modelling solar cells with different system scales, from the electronic to macroscopic level References, in a single resource, state-of-the-art techniques in modelling, optimization and design of DSSC
Author: Mariyappan Shanmugam
Publisher:
ISBN:
Category : Dye-sensitized solar cells
Languages : en
Pages : 430
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Book Description
Author: R. Navanietha Krishnaraj
Publisher: John Wiley & Sons
ISBN: 1119538548
Category : Science
Languages : en
Pages : 560
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Book Description
An introduction to the fundamental concepts and rules in bioelectrochemistry and explores latest advancements in the field Bioelectrochemical Interface Engineering offers a guide to this burgeoning interdisciplinary field. The authors—noted experts on the topic—present a detailed explanation of the field’s basic concepts, provide a fundamental understanding of the principle of electrocatalysis, electrochemical activity of the electroactive microorganisms, and mechanisms of electron transfer at electrode-electrolyte interfaces. They also explore the design and development of bioelectrochemical systems. The authors review recent advances in the field including: the development of new bioelectrochemical configurations, new electrode materials, electrode functionalization strategies, and extremophilic electroactive microorganisms. These current developments hold the promise of powering the systems in remote locations such as deep sea and extra-terrestrial space as well as powering implantable energy devices and controlled drug delivery. This important book: • Explores the fundamental concepts and rules in bioelectrochemistry and details the latest advancements • Presents principles of electrocatalysis, electroactive microorganisms, types and mechanisms of electron transfer at electrode-electrolyte interfaces, electron transfer kinetics in bioelectrocatalysis, and more • Covers microbial electrochemical systems and discusses bioelectrosynthesis and biosensors, and bioelectrochemical wastewater treatment • Reviews microbial biosensor, microfluidic and lab-on-chip devices, flexible electronics, and paper and stretchable electrodes Written for researchers, technicians, and students in chemistry, biology, energy and environmental science, Bioelectrochemical Interface Engineering provides a strong foundation to this advanced field by presenting the core concepts, basic principles, and newest advances.
Author: Songyuan Dai
Publisher: Walter de Gruyter GmbH & Co KG
ISBN: 311038373X
Category : Technology & Engineering
Languages : en
Pages : 706
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Book Description
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: I-Kang Ding
Publisher: Stanford University
ISBN:
Category :
Languages : en
Pages : 126
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Book Description
Dye-sensitized solar cells (DSCs) are among the promising photovoltaic technologies that could potentially replace the expensive silicon. Liquid electrolyte-based DSCs have the highest efficiency but they suffer from potential stability and encapsulation problems when manufactured at high volumes. Research groups are actively pursuing solid state dye-sensitized solar cells (ss-DSCs), which uses a solid-state hole-transport material to replace the liquid electrolyte. SS-DSCs can potentially achieve higher power conversion efficiencies than the liquid-electrolyte because the open-circuit voltage can be adjusted by the choice of different hole-transport materials. However, current ss-DSCs are limited by both pore filling and electron-hole recombination such that the optimal thickness is around 2 microns, far thinner than the thickness needed to achieve good optical absorption. This thesis presents results that address two challenges facing the field of ss-DSC research - what is limiting the thickness of the device, and what can we do to boost light absorption and power conversion efficiency? In the first part, we describe how pore filling of hole-transport materials inside mesoporous TiO2 films is a limiting factor to the device thickness. This is accomplished by three closely-related pore filling projects: (a) quantifying the pore filling of hole-transport materials inside mesoporous TiO2 films; (b) experimenting with new methods to improve pore filling fraction; and (c) investigating the effect of pore filling on photovoltaic performances of ss-DSCs and the underlying photophysical mechanisms. This brings new physical understanding of the importance of pore filling and how pore filling a effects the photovoltaic performances. In the second part, we describe a new device architecture to increase the absorption through the use of plasmonic back reectors, which consist of two-dimensional (2D) array of silver nanodomes. They are incorporated into the ss-DSCs by nanoimprint lithography, and they enhance absorption through excitation of plasmonic modes and increased light scattering.
Author: Alagarsamy Pandikumar
Publisher: John Wiley & Sons
ISBN: 111955733X
Category : Science
Languages : en
Pages : 288
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Book Description
Offers an Interdisciplinary approach to the engineering of functional materials for efficient solar cell technology Written by a collection of experts in the field of solar cell technology, this book focuses on the engineering of a variety of functional materials for improving photoanode efficiency of dye-sensitized solar cells (DSSC). The first two chapters describe operation principles of DSSC, charge transfer dynamics, as well as challenges and solutions for improving DSSCs. The remaining chapters focus on interfacial engineering of functional materials at the photoanode surface to create greater output efficiency. Interfacial Engineering in Functional Materials for Dye-Sensitized Solar Cells begins by introducing readers to the history, configuration, components, and working principles of DSSC It then goes on to cover both nanoarchitectures and light scattering materials as photoanode. Function of compact (blocking) layer in the photoanode and of TiCl4 post-treatment in the photoanode are examined at next. Next two chapters look at photoanode function of doped semiconductors and binary semiconductor metal oxides. Other chapters consider nanocomposites, namely, plasmonic nanocomposites, carbon nanotube based nanocomposites, graphene based nanocomposites, and graphite carbon nitride based nanocompositesas photoanodes. The book: Provides comprehensive coverage of the fundamentals through the applications of DSSC Encompasses topics on various functional materials for DSSC technology Focuses on the novel design and application of materials in DSSC, to develop more efficient renewable energy sources Is useful for material scientists, engineers, physicists, and chemists interested in functional materials for the design of efficient solar cells Interfacial Engineering in Functional Materials for Dye-Sensitized Solar Cells will be of great benefit to graduate students, researchers and engineers, who work in the multi-disciplinary areas of material science, engineering, physics, and chemistry.
Author: George Yan Margulis
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Dye-sensitized solar cells (DSCs) offer a variety of advantages to typical silicon and thin film solar cells. And while the advantages of ease-of-processing and fabrication from low-cost, earth-abundant materials make DSCs an attractive technology, the efficiency of DSCs (13%) is still too low to compete with the current inorganic incumbents. Hence, new 'outside-of-the-box' strategies must be used to render DSCs competitive with current commercial technologies. This thesis describes my work on identifying losses in DSCs and 2 strategies to improve the efficiency of DSCs: the use of highly-soluble energy relay days to broaden the spectral response of DSCs, and the fabrication of semi-transparent solid-state DSCs to help improve the efficiency of inorganic devices in a tandem solar cell. Solid-state dye-sensitized solar cells (ssDSCs) have historically lagged behind their liquid-electrolyte counterparts in efficiency. To gain a better understanding of why this is so, we have developed accurate internal quantum efficiency (IQE) measurements for ssDSCs. By analyzing the IQE, it is found that while charge collection is efficient in ssDSCs, often charge injection is not. This analysis also shows that parasitic absorption by the Spiro-OMeTAD is an important loss mechanism in ssDSCs and suggests that stronger absorbing sensitizers are the most promising path to higher efficiencies. In DSCs, the roles of absorbing light, injecting charge, and blocking recombination are all given to the sensitizing dye, resulting in a myriad of design rules for DSC sensitizers. An energy relay dye (ERD) is a second dye that helps relax these design rules by providing complementary absorption and then transferring energy to a sensitizing dye. However, such ERDs come with their own design rules, including the need for high solubility for full light absorption, and high photoluminescence for efficient energy transfer. We have designed and synthesized two such dyes, and characterized them as ERDs in DSCs, yielding a 65% increase in efficiency. Finally, even if DSCs are unable to reach efficiencies that render them competitive against traditional inorganic solar cells, DSCs can be used in conjunction with an inorganic solar cell in a hybrid tandem photovoltaic (HTPV). High open-circuit voltages and cheap processing render DSCs attractive top cells in HTPVs, and such devices can exceed efficiencies of 20%. However, in order to be used in HTPVs, a DSC must be fabricated such that below bandgap light can pass through the device and be absorbed by the inorganic bottom cell. Toward that end, we have developed a transparent top contact for solid-state dye-sensitized solar cells that renders ssDSCs attractive candidates for HTPVs.
Author: Pankaj Kumar
Publisher: CRC Press
ISBN: 1315353628
Category : Science
Languages : en
Pages : 452
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Book Description
This book contains detailed information on the types, structure, fabrication, and characterization of organic solar cells (OSCs). It discusses processes to improve efficiencies and the prevention of degradation in OSCs. It compares the cost-effectiveness of OSCs to those based on crystalline silicon and discusses ways to make OSCs more economical. This book provides a practical guide for the fabrication, processing, and characterization of OSCs and paves the way for further development in OSC technology.
