Spectroscopic Study of Charge-transfer States in Organic Semiconductors PDF Download
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Author: Yun Liu
Publisher:
ISBN:
Category :
Languages : en
Pages : 90
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Book Description
To achieve net zero carbon emission required for a sustainable economy, global energy production requires a clean and reliable solution. Photovoltaic technology that directly converts sunlight into electricity has demonstrated its potential in contributing to a carbon free energy future. Among myriad solar technologies, photovoltaic cells based on organic semiconductors offer unique advantages of being light weight, flexible and low cost and have shown promising photovoltaic performance with efficiency climbing over 18%. In state-of-the-art organic solar cells, a mixture of polymer electron donor and electron acceptor molecules converts light energy to electrical energy. The rapid performance advancement from 11% to over 18% in recent years is largely achieved by the replacement of fullerene molecules with small molecules as electron acceptors, known as non-fullerene acceptors. These new materials not only unlock promising photovoltaic performance but more importantly pose new photophysical questions that challenge the research community’s original understanding of organic solar cells and suggest new design rules. Central to the photophysics of organic solar cells, as reviewed in Chapter 1, is the charge-transfer state formed between the electron donor molecular and the acceptor molecule. The work presented in this thesis focuses on understanding the properties of the charge-transfer state and its role in mediating energy loss in solar cells. Contrary to the traditional model in which significant driving energy is required to separate tightly bound electron-hole pair in the charge-transfer state, one surprising finding to the organic solar cell community is that the most efficient polymer/non-fullerene organic photovoltaics have negligible driving force for charge separation. Furthermore, compared to fullerene acceptors, non-fullerene acceptors have appreciable absorption, implying that charge generation via hole transfer from acceptor to donor could play an important role. In Chapter 2, via detailed time-resolved and steady state spectroscopic studies, we discover a slow yet efficient generation of the charge-transfer state and charge carriers via hole transfer using a model blend of polymer and non-fullerene acceptors. Our findings also allude to a new photophysical scheme in charge generation that was not observed in polymer/fullerene blends but important to efficient polymer/non-fullerene acceptor blends. Another remarkable property of many efficient polymer/non-fullerene blends is their high photoluminescence efficiency and consequently small non-radiative recombination loss, suggesting that "a great solar cell is also a great light emitting diode" also applies to organic solar cells and prompting research efforts on improving the luminescence efficiency of charge-transfer states. Based on Shockley-Queisser’s theoretical framework, an ideal solar cell should only suffer energy loss from radiative recombination as it is unavoidable, and that any non-radiative recombination is excess. In organic solar cells, however, due to molecular vibrations, non-radiative recombination loss contributes a significant amount to total energy loss. Current research efforts have shown that the non-radiative recombination loss follows an energy-gap law where higher gap materials have intrinsically lower loss. Moreover, photoluminescence yield of the charge-transfer state can be limited by that of the local exciton of the lower bandgap material when these states quantum mechanically mix. In Chapter 3, I combine spectroscopic methods and molecular dynamic calculations to examine in detail what molecular properties determine photoluminescence yield of the charge-transfer state and non-radiative recombination loss of the solar cell. After demonstrating an intrinsically emissive yet charge-generating small molecule blend, I show that due to wavefunction mixing between the charge-transfer state and the local exciton, both photoluminescence quantum yield and lifetime of the local exciton influences emission of the charge-transfer state. The latter is a new consideration for selecting materials for efficient organic photovoltaics and light emitting diodes. In Chapter 4, I propose and show current progress on a previously overlooked spectroscopy method directly detecting wavefunction mixing between the charge-transfer state and the local exciton of non-fullerene acceptor molecules. Our findings and proposal provide direction for molecular design and material selection to limit energy loss in organic solar cells.
Author: Yun Liu
Publisher:
ISBN:
Category :
Languages : en
Pages : 90
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Book Description
To achieve net zero carbon emission required for a sustainable economy, global energy production requires a clean and reliable solution. Photovoltaic technology that directly converts sunlight into electricity has demonstrated its potential in contributing to a carbon free energy future. Among myriad solar technologies, photovoltaic cells based on organic semiconductors offer unique advantages of being light weight, flexible and low cost and have shown promising photovoltaic performance with efficiency climbing over 18%. In state-of-the-art organic solar cells, a mixture of polymer electron donor and electron acceptor molecules converts light energy to electrical energy. The rapid performance advancement from 11% to over 18% in recent years is largely achieved by the replacement of fullerene molecules with small molecules as electron acceptors, known as non-fullerene acceptors. These new materials not only unlock promising photovoltaic performance but more importantly pose new photophysical questions that challenge the research community’s original understanding of organic solar cells and suggest new design rules. Central to the photophysics of organic solar cells, as reviewed in Chapter 1, is the charge-transfer state formed between the electron donor molecular and the acceptor molecule. The work presented in this thesis focuses on understanding the properties of the charge-transfer state and its role in mediating energy loss in solar cells. Contrary to the traditional model in which significant driving energy is required to separate tightly bound electron-hole pair in the charge-transfer state, one surprising finding to the organic solar cell community is that the most efficient polymer/non-fullerene organic photovoltaics have negligible driving force for charge separation. Furthermore, compared to fullerene acceptors, non-fullerene acceptors have appreciable absorption, implying that charge generation via hole transfer from acceptor to donor could play an important role. In Chapter 2, via detailed time-resolved and steady state spectroscopic studies, we discover a slow yet efficient generation of the charge-transfer state and charge carriers via hole transfer using a model blend of polymer and non-fullerene acceptors. Our findings also allude to a new photophysical scheme in charge generation that was not observed in polymer/fullerene blends but important to efficient polymer/non-fullerene acceptor blends. Another remarkable property of many efficient polymer/non-fullerene blends is their high photoluminescence efficiency and consequently small non-radiative recombination loss, suggesting that "a great solar cell is also a great light emitting diode" also applies to organic solar cells and prompting research efforts on improving the luminescence efficiency of charge-transfer states. Based on Shockley-Queisser’s theoretical framework, an ideal solar cell should only suffer energy loss from radiative recombination as it is unavoidable, and that any non-radiative recombination is excess. In organic solar cells, however, due to molecular vibrations, non-radiative recombination loss contributes a significant amount to total energy loss. Current research efforts have shown that the non-radiative recombination loss follows an energy-gap law where higher gap materials have intrinsically lower loss. Moreover, photoluminescence yield of the charge-transfer state can be limited by that of the local exciton of the lower bandgap material when these states quantum mechanically mix. In Chapter 3, I combine spectroscopic methods and molecular dynamic calculations to examine in detail what molecular properties determine photoluminescence yield of the charge-transfer state and non-radiative recombination loss of the solar cell. After demonstrating an intrinsically emissive yet charge-generating small molecule blend, I show that due to wavefunction mixing between the charge-transfer state and the local exciton, both photoluminescence quantum yield and lifetime of the local exciton influences emission of the charge-transfer state. The latter is a new consideration for selecting materials for efficient organic photovoltaics and light emitting diodes. In Chapter 4, I propose and show current progress on a previously overlooked spectroscopy method directly detecting wavefunction mixing between the charge-transfer state and the local exciton of non-fullerene acceptor molecules. Our findings and proposal provide direction for molecular design and material selection to limit energy loss in organic solar cells.
Author: Kohzoh Masuda
Publisher: Springer Science & Business Media
ISBN: 1468421093
Category : Science
Languages : en
Pages : 187
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Book Description
Great progress has been made in the field of ordinary semiconductor physics and associated technologies. For the time being, if we could use new materials such as organic semiconductors progress in electronics could be accelerated. Characteristics of organic semiconductors that are superior to others are: i) high photo-conductivity under irradiation along with low leakage current in the dark, ii) high sensitivity of the conductivity to various gases and to pressure. iii) possibility of using them in the amorphous state, iv) possibility of making devices of extremely small size, v) large variety of the materials, which makes suitable choice of material component easy. A possible future development is a highly conductive material which could be used for electric power transmission - and which might help solve some of the problems posed by transmission losses. The U.S.-Japan Seminar on Energy and Charge Transfer in Organic Semiconductors was held in Osaka Japan, 6-9 August, 1973. Completed results were summarized and the direction for the future was discussed. Information was exchanged quite freely and actively in a pleasant atmosphere. Many of the papers presented at the seminar are published here but unfortunately a few could not be included. It would give us great pleasure if this seminar could be one step in the further development of the research in this field.
Author: Thorsten U. Kampen
Publisher: John Wiley & Sons
ISBN: 3527643745
Category : Science
Languages : en
Pages : 258
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Book Description
This up-to-date reference for students and researchers in the field is the first systematic treatment on the property measurements of organic semiconductor materials. Following an introduction, the book goes on to treat the structural analysis of thin films and spectroscopy of electronic states. Subsequent sections deal with optical spectroscopy and charge transport. An invaluable source for understanding, handling and applying this key type of material for physicists, materials scientists, graduate students, and analytical laboratories.
Author: U. S. Japan Seminar on Energy and Charge Transfer Staff
Publisher:
ISBN: 9780608054735
Category :
Languages : en
Pages : 210
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Book Description
Author: Sinhang Cheung
Publisher:
ISBN:
Category : Admittance spectroscopy
Languages : en
Pages : 134
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Book Description
Traps are ubiquitously present in semiconductors. Their presence results in ineffective charge transport and thus limited the device performance. For organic semiconductors, traps can present intrinsically via structural disorder or extrinsically during synthesis or device fabrication. A thorough understanding of traps is important to optimize the device performance and material design. This thesis employs two trap measurement techniques, photothermal deflection spectroscopy (PDS) and thermal admittance spectroscopy (TAS), to investigate the trap density in the materials. The subgap optical absorptions of several high performance bulk-heterojunction (BHJ) systems for organic solar cells have been studied by PDS. The charge transfer (CT) states are, in particular, looked into detail. CT states are intermediate bound electron-hole pairs at the donor/acceptor (D/A) interface of an organic solar cell. The dynamics and energetics of CT states are crucial to free charge generation and recombination processes. With the help of PDS and external quantum efficiency (EQE) measurements, the CT states the delocalized CT states (hot) from the localized CT states (cold) are observed and differentiated directly. It is discovered that the localized CT states are more pronounced when the acceptor concentration reaches its percolation limit. As the acceptor concentration reaches its optimized composition, the intensity of these CT states is significantly reduced due to the reduced recombination. Using the CT energies measured from PDS, the open-circuit voltage losses from the BHJs are determined. Besides PDS, thermal admittance spectroscopy (TAS) is employed as an alternative method to measure the trap densities. TAS measures the frequency dependent capacitance response of a semiconductor under a small ac signal excitation. This technique is useful to measure the trap depth and trap density of a semiconductor. The defect profiles in two classes of materials are investigated, they are perovskite compounds and an organic hole transporter with an intentional dopant. The trap density are determined by TAS is compared with that obtained by PDS.
Author: Ana Sylvia Acosta
Publisher:
ISBN:
Category :
Languages : en
Pages : 334
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Book Description
Author: Anna Köhler
Publisher: John Wiley & Sons
ISBN: 3527332928
Category : Technology & Engineering
Languages : en
Pages : 436
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Book Description
The first advanced textbook to provide a useful introduction in a brief, coherent and comprehensive way, with a focus on the fundamentals. After having read this book, students will be prepared to understand any of the many multi-authored books available in this field that discuss a particular aspect in more detail, and should also benefit from any of the textbooks in photochemistry or spectroscopy that concentrate on a particular mechanism. Based on a successful and well-proven lecture course given by one of the authors for many years, the book is clearly structured into four sections: electronic structure of organic semiconductors, charged and excited states in organic semiconductors, electronic and optical properties of organic semiconductors, and fundamentals of organic semiconductor devices.
Author: Lian Duan
Publisher: Woodhead Publishing
ISBN: 0128227737
Category : Technology & Engineering
Languages : en
Pages : 490
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Book Description
Thermally Activated Delayed Fluorescence Organic Light-Emitting Diodes (TADF-OLEDs) comprehensively introduces the history of TADF, along with a review of fundamental concepts. Then, TADF emitters with different colors, such as blue, green, red and NIR as well as white OLEDs are discussed in detail. Other sections cover exciplex-type TADF materials, emerging application of TADF emitters as a host in OLEDs, and applications of TADF materials in organic lasers and biosensing. - Discusses green, blue, red, NIR and white TADF emitters and their design strategies for improved performance for light-emitting diode applications - Addresses emerging materials, such as molecular and exciplex-based TADF materials - Includes emerging applications like lasers and biosensors
Author: Jean-Pierre Farges
Publisher: CRC Press
ISBN: 1000723585
Category : Technology & Engineering
Languages : en
Pages : 874
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Book Description
This work examines all aspects of organic conductors, detailing recent theoretical concepts and current laboratory methods of synthesis, measurement, control and analysis. It describes advances in molecular-scale engineering, including switching and memory systems, Schottky and electroluminescent diodes, field-effect transistors, and photovoltaic devices and solar cells.
Author: Yufeng Zhang
Publisher:
ISBN:
Category :
Languages : en
Pages : 266
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Book Description
Abstract: Organic semiconductors have several unique properties, different from traditional inorganic semiconductors, such as flexibility and low cost production on a large scale. Potentially, they can be used in several new optoelectronic devices, such as organic solar cells, and organic light-emitting devices (OLEDs) Phthalocyanines (Pc's) are one important type of molecular organic semiconductor. The ease with which a diverse set of cations can bond to the phthalocyanine ligand leads to Pc-based thin films that display a wide variety of optical and electrical properties. In these materials, the ligand has a complex electronic structure in itself, and the introduction of metal cations adds further complexity to the states near the Fermi level (E F) due to the overlap of metal d states with carbon and nitrogen 2p states. In this thesis, the electronic structure of several Pc's has been studied by soft x-ray spectroscopies, such as x-ray photoemission spectroscopy (XPS), x-ray absorption spectroscopy (XAS), and x-ray emission spectroscopy (XES). To avoid potential contamination and beam damage, the large area thin film samples have been prepared in situ by using organic molecular beam deposition (OMBD). The structure of samples were characterized ex situ by scanning electron microscopy (SEM) and X-ray diffraction (XRD). The soft x-ray spectra recorded from stationary samples are found to represent the electronic structure from damaged molecules, which is caused by intense x-ray beams. Continuously translating samples during measurement overcomes this problem. Element, chemical, and symmetry specific occupied and unoccupied partial density of states (PDOS) from Pc's were observed. They show good agreement with density functional theory (DFT) calculations. Studies of potassium doping non-transition metal Pc, fluorinated metal Pc, and metal oxide Pc's show several interesting phenomena, such as variation of molecular symmetry, and charge transfer and d-d* resonant inelastic x-ray scattering (RIXS) features. These observations and comparisons with other organic semiconductors, such as Tri (8-hydroxyquinoline) aluminum (Alq3), and metal oxides, such as V 2 O 3, not only help to deepen our understanding of the optical and electrical properties of Pc's, but also provide valuable information for the studies of other materials.
