Molecular Structures And Device Properties Of Organic Solar Cells

Molecular Structures and Device Properties of Organic Solar Cells

Author : Zhenghao Mao

Publisher :

Page : 198 pages

File Size : 44,94 MB

Release : 2014

Category :

ISBN :

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Book Description

Organic solar cells (OSCs), consisted of carbon-based organic semiconductors, either polymers or small molecules, have recently attracted the attention of both academic and industry due to their unique properties such as easy processing, flexibility and scalability. One major limitation toward commercialization is the low power conversion efficiency (PCE) compared to inorganic solar cells. Thus, much research in this field is focused on improving the efficiency. A better understanding to the relationship between the properties of organic semiconductors and the solar device performance is required. In this thesis, perfluorinated-end modified poly(3-hexylthiophene), core-substituted naphthalene diimide, and Zn (II) complexes with azadipyrromethene were investigated. Their properties and applications in organic photovolatic (OPV) are discussed.Previous studies suggested that end-group modification of P3HT affects device efficiency, and that some fluorine in the end group slightly improve the efficiency. In order to further understand how perfluorinated end-groups affect device performance of blends of poly(3-hexylthiophene) (P3HT) and 1-(3-methoxycarbonyl) propyl-1-phenyl [6, 6] C61 (PCBM), we synthesized a series of well-defined P3HT with differing perfluoroalkyl length by Stille coupling of the bromine end of P3HT and stannylated 2-perfluoroalkylthiophene. The reactions occurred quantitatively, confirmed by 1H and 19F NMR spectroscopy, and by MALDI-ToF mass spectroscopy. Electron filtering transmission electron microscopy (EF-TEM) revealed that the polymer/PCBM phase separate on the nanoscale. However, solar cells of the modified P3HTs with PCBM had a lower power conversion efficiency than that of un-modified P3HT:PCBM, suggesting that perfluoroalkyl end-groups are detrimental to solar cell performance.The performance of solution-processed organic photovoltaic is seriously limited by the absorption and energy tuning potential of fullerene-based electron acceptors. Overcoming these limitations requires the development of non-fullerene acceptors. Core-substituted naphthalene diimides (cNDI) are good candidates as non-fullerene acceptors for organic photovoltaic, because they have high electron affinity, excellent electron transport properties, and tunable energy levels. We synthesized several cNDIs with different imide core substituents and different alkylamino substituents (RF1-6). Their optical and electrochemical properties and OPV device properties as electron acceptors were studied. Particularly, RF1 was investigated as electron accepting material for optimization of solar cells. The LUMO energy level of RF1 is -3.7 eV, higher than PCBM (-4.0 eV); correspondingly, a high Voc (~1 V) can be reached from blends of P3HT and RF1. The power conversion efficiency improves from 0.31% (as-casted) or 0.48% (pre-annealed) to 0.96% with a processing 1,8-diiodooctane(DIO) additive at an optimum concentration of 0.2 vol%. The results are explained by changes in morphology observed by atomic force microscopy (AFM) and transmitting electron microscopy (TEM) images. Charge transport properties were estimated by space-charge limited current (SCLC) model, indicating that the electron mobility determines the OSC performance.One reason why efficiency of non-fullerene based solar cell have been relatively low is partly because non-fullerene acceptors are often planar and tend to form unfavorable phase-separated domains when blended with typical donors. We synthesized and characterized a series of new solution-processable azadipyromethene-based complexes, Zn(WS1-5)2. These new complexes have high electron affinity and strong accepting properties, and behave as good electron acceptors in organic solar cells. The best device performance was obtained from Zn(WS3)2 acceptor. The 3D nature of this acceptor prevents crystallization and promotes a favorable nanoscale morphology to give a high PCE of 4.10%. The acceptor also significantly contributed to photocurrent generation by harvesting light between 600 nm and 800 nm. These results demonstrate a new paradigm to designing acceptors with tunable properties that can overcome the limitations of fullerenes.



Organic Solar Cells

Author : Liming Ding

Publisher : John Wiley & Sons

Page : 988 pages

File Size : 12,25 MB

Release : 2022-02-09

Category : Technology & Engineering

ISBN : 3527833668

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Book Description

Organic Solar Cells A timely and singular resource on the latest advances in organic photovoltaics Organic photovoltaics are gaining widespread attention due to their solution processability, tunable electronic properties, low temperature manufacture, and cheap and light materials. Their wide range of potential applications may result in significant near-term commercialization of the technology. In Organic Solar Cells: Materials Design, Technology and Commercialization, renowned scientist Dr. Liming Ding delivers a comprehensive exploration of organic solar cells, including discussions of their key materials, mechanisms, molecular designs, stability features, and applications. The book presents the most state-of-the-art developments in the field alongside fulsome treatments of the commercialization potential of various organic solar cell technologies. The author also provides: Thorough introductions to fullerene acceptors, polymer donors, and non-fullerene small molecule acceptors Comprehensive explorations of p-type molecular photovoltaic materials and polymer-polymer solar cell materials, devices, and stability Practical discussions of electron donating ladder-type heteroacenes for photovoltaic applications In-depth examinations of chlorinated organic and single-component organic solar cells, as well as the morphological characterization and manipulation of organic solar cells Perfect for materials scientists, organic and solid-state chemists, and solid-state physicists, Organic Solar Cells: Materials Design, Technology and Commercialization will also earn a place in the libraries of surface chemists and physicists and electrical engineers.



Organic Solar Cells

Author : Pankaj Kumar

Publisher : CRC Press

Page : 452 pages

File Size : 28,40 MB

Release : 2016-10-03

Category : Science

ISBN : 1315353628

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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.



Organic Solar Cells

Author : Barry P. Rand

Publisher : CRC Press

Page : 795 pages

File Size : 50,7 MB

Release : 2014-08-26

Category : Science

ISBN : 9814463663

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Book Description

Organic photovoltaic (OPV) cells have the potential to make a significant contribution to the increasing energy needs of the future. In this book, 15 chapters written by selected experts explore the required characteristics of components present in an OPV device, such as transparent electrodes, electron- and hole-conducting layers, as well as elect



Correlating structure and function in small molecule organic solar cells by means of scanning probe and electron microscopy

Author : Michael Scherer

Publisher : BoD – Books on Demand

Page : 202 pages

File Size : 35,1 MB

Release : 2016-07-20

Category : Science

ISBN : 3741251526

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Book Description

In this work nanoscale properties in active layers of small molecule organic solar cells are studied regarding their impact on device performance. For this, the effect of variations in stack design and process conditions is examined both electrically and with high resolution imaging techniques. Two topics are addressed: (i) the visualization of charge extraction/injection properties of solar cell contacts and (ii) the tailoring of structural properties of co-evaporated material blends for bulk heterojunction (BHJ) organic solar cells. (i) We study the impact of controlled contact manipulation on the internal electric potential distribution of fluorinated zincphtalocyanine (F4ZnPc)/fullerene (C60) organic solar cells under operating conditions. In a detailed analytical study using photoelectron spectroscopy and in-operando scanning Kelvin probe microscopy it is demonstrated that the electric field distribution of organic solar cells at the maximum power point depends in an overproportional manner on contact properties and ranges from bulk to contact dominated even for solar cells with decent device performance. (ii) The morphology of co-evaporated active layer blends depends on both substrate and substrate temperature. Here we study the morphology of F4ZnPc:C60 blends with analytical transmission electron microscopy. For all substrates used is found that co-evaporation of the materials at elevated substrate temperature (100° Cel) induces a distinct phase segregation of F4ZnPc and C60. However, only when using a C60 underlayer, as in inverted devices, also the crystallinity of the segregated C60 phase increases. There is only a slight increase in crystallinity when F4ZnPc acts as an underlayer, as typically for non-inverted devices. Solar cell characterization reveals that the crystalline C60 domains are the main driving force for enhanced free charge carrier generation and higher power conversion efficiencies. With this we could provide a novel explanation why record efficiencies of small molecule organic solar cells are realized in inverted device architecture only.



Organic Solar Cells

Author : Ingmar Bruder

Publisher :

Page : pages

File Size : 46,73 MB

Release : 2010

Category :

ISBN :

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Organic Solar Cells

Author : Wallace C.H. Choy

Publisher : Springer Science & Business Media

Page : 268 pages

File Size : 20,27 MB

Release : 2012-11-19

Category : Technology & Engineering

ISBN : 1447148231

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Book Description

Organic solar cells have emerged as new promising photovoltaic devices due to their potential applications in large area, printable and flexible solar panels. Organic Solar Cells: Materials and Device Physics offers an updated review on the topics covering the synthesis, properties and applications of new materials for various critical roles in devices from electrodes, interface and carrier transport materials, to the active layer composed of donors and acceptors. Addressing the important device physics issues of carrier and exciton dynamics and interface stability and novel light trapping structures, the potential for hybrid organic solar cells to provide high efficiency solar cells is examined and discussed in detail. Specific chapters covers key areas including: Latest research and designs for highly effective polymer donors/acceptors and interface materials Synthesis and application of highly transparent and conductive graphene Exciton and charge dynamics for in-depth understanding of the mechanism underlying organic solar cells. New potentials and emerging functionalities of plasmonic effects in OSCs Interface Degradation Mechanisms in organic photovoltaics improving the entire device lifetime Device architecture and operation mechanism of organic/ inorganic hybrid solar cells for next generation of high performance photovoltaics This reference can be practically and theoretically applied by senior undergraduates, postgraduates, engineers, scientists, researchers, and project managers with some fundamental knowledge in organic and inorganic semiconductor materials or devices.



Organic, Inorganic and Hybrid Solar Cells

Author : Ching-Fuh Lin

Publisher : John Wiley & Sons

Page : 278 pages

File Size : 11,86 MB

Release : 2012-09-04

Category : Technology & Engineering

ISBN : 1118168534

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Book Description

Provides detailed descriptions of organic, inorganic, and hybrid solar cells and the latest developments in the quest to produce low-cost, long-lasting solar cells What will it take to transform solar energy from an important alternative source to a truly competitive and, perhaps, dominant one? Lower cost and longer life. Organic, Inorganic, and Hybrid Solar Cells: Principles and Practice provides in-depth information on the three types of existing solar cells, giving readers a good foundation for evaluating the technologies with the most potential for competing with energy from fossil fuels. Featuring a Foreword written by Nobel Peace Prize co-winner Dr. Woodrow W. Clark, this timely and comprehensive guide: Focuses on the realization of low-cost and long-life solar cells study and applications Reviews the properties of inorganic materials, primarily semiconductors Explores the electrical and optical properties of organic materials Discusses the interfacing of organic and inorganic materials: compatibility of deposition, the adhesion problem, formation of surface states, and band-level realignment Provides a detailed description of organic-inorganic hybrid solar cells, from the basic principles to practical devices Introduces a sandwiched structure for hybrid solar cells, which combines a far lower production cost than inorganic solar cells while stabilizing and extending the life of organic material far beyond that of organic solar cells Organic, Inorganic, and Hybrid Solar Cells: Principles and Practice is a first-rate professional reference for electrical engineers and important supplemental reading for graduate students in related areas of study.



Electronic Structure of ?-Conjugated Materials and Their Effect on Organic Photovoltaics

Author : Chuanfei Wang

Publisher : Linköping University Electronic Press

Page : 84 pages

File Size : 15,69 MB

Release : 2017-11-15

Category :

ISBN : 9176853934

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Book Description

The great tunability of structure and electronic properties of ?-conjugated organic molecules/polymers combined with other advantages such as light weight and flexibility etc., have made organic-based electronics the focus of an exciting still-growing field of physics and chemistry for more than half a century. The application of organic electronics has led to the appearance of wide range of organic electronic devices mainly including organic light emitting diodes (OLED), organic field effect transistors (OFET) and organic solar cells (OSC). The application of the organic electronic devices mainly is limited by two dominant parameters, i.e., their performance and stability. Up to date, OLED has been successfully commercialized in the market while the OSC are still on the way to commercialization hindered by low efficiency and inferior stability. Understanding the energy levels of organic materials and energy level alignment of the devices is crucial to control the efficiency and stability of the OSC. In this thesis, energy levels measured by different methods are studied to explore their relationship with device properties, and the strategies on how to design efficient and stable OSC based on energy level diagrams are provided. Cyclic Voltammetry (CV) is a traditional and widely used method to probe the energy levels of organic materials, although there is little consensus on how to relate the oxidation/reduction potential ((Eox/Ered) to the vacuum level. Ultraviolet Photoelectron Spectroscopy (UPS) can be used to directly detect vertical ionization potential (IP) of organic materials. In this thesis, a linear relationship of IP and Eox was found, with a slope equal to unity. The relationship provides for easy conversion of values obtained by the two techniques, enabling complementarily use in designing and fabricating efficient and stable OSC. A popular rule of thumb is that the offset between the LUMO levels of donor and acceptor should be 0.3 eV, according to which a binary solar cell with the minimum voltage losses around 0.49 V was designed here. Introduction of the ternary blend as active layer is an efficient way to improve both efficiency and stability of the OSC. Based on our studied energy-level diagram within the integer charge transfer (ICT) model, we designed ternary solar cells with enhanced open circuit voltage for the first time and improved thermal stability compared to reference binary ones. The ternary solar cell with minimum voltage losses was developed by combining two donor materials with same ionization potential and positive ICT energy while featuring complementary optical absorption. Furthermore, the fullerene acceptor was chosen so that the energy of the positive ICT state of the two donor polymers is equal to the energy of negative ICT state of the fullerene, which can enhance dissociation of all polymer donor and fullerene acceptor excitons and suppress bimolecular and trap-assistant recombination. Rapid development of non-fullerene acceptors in the last two years affords more recipes of designing both efficient and stabile OSC. We show in this thesis how non-fullerene acceptors successfully can be used to design ternary solar cells with both enhanced efficiency and thermal stability. Besides improving the efficiency of the devices, understanding of the stability and degradation mechanism is another key issue. The degradation of conjugated molecules/polymers often follow many complicated pathways and at the same time many factors for degradation are coupled with each other. Therefore, the degradation of non-fullerene acceptors was investigated in darkness by photoelectron spectroscopy in this thesis with the in-situ method of controlling exposure of O2 and water vapor separately.



Polymer Photovoltaics

Author : Fei Huang

Publisher : Royal Society of Chemistry

Page : 422 pages

File Size : 40,74 MB

Release : 2015-09-08

Category : Science

ISBN : 1782622306

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Book Description

Polymer solar cells have gained much attention as they offer a potentially economic and viable way of commercially manufacturing lightweight, flexible and low-cost photovoltaics. With contributions from leading scientists, Polymer Photovoltaics provides an international perspective on the latest research for this rapidly expanding field. The book starts with an Introduction to polymer solar cells and covers several important topics that govern their photovoltaic properties including the chemistry and the design of new light harvesting and interfacial materials and their structure-property relationship; the physics for photocurrent generation in the polymer solar cells; new characterization tools to study morphology effect on the property of donor/acceptor bulk heterojunctions; new device concepts such as tandem cells and semi-transparent cells and advanced roll-to-roll processes for large-scale manufacturing of polymer solar cells. Written by active researchers, the book provides a comprehensive overview of the recent advancements in polymer solar cell technology for both researchers and students that are interested in this field.