Design And Optimization Of Colloidal Quantum Dot Solids For Enhanced Charge Transport And Photovoltaics

Design and Optimization of Colloidal Quantum Dot Solids for Enhanced Charge Transport and Photovoltaics

Author : Sangjin Lee (Ph. D.)

Publisher :

Page : pages

File Size : 31,9 MB

Release : 2016

Category :

ISBN :

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Colloidal quantum dots (CQDs) have attracted much attention due to their distinctive optical properties such as wide spectral responses and tunable absorption spectra with simple size control. These properties, together with the advantages of solution processing and superior robustness to organic materials, have motivated the recent investigation of CQD-based solar cells, which have seen rapid growth in power conversion efficiency in just the last 10 years, to a current record of over 10%. However, in order to continue to push the efficiencies higher, a better understanding of the charge transport phenomena in CQD films is needed. While the carrier transport mechanisms between isolated molecules have been explored theoretically and the device-scale mobility of CQD layers has been characterized using experimental measurements such as time-of-flight analysis and field-effect-transistor measurements, a systematic study of the connection between these two distinct scales is required in order to provide crucial information regarding how CQD layers with higher charge carrier mobility can be achieved. While a few strategies such as ligand exchanges, band-like transport, and trap-state-mediated transport have been suggested to enhance the charge carrier mobility, inhomogeneity in CQD solids has been considered a source of the mobility degradation because the electronic properties in individual CQDs may have dispersions introduced in the synthesis and/or in the deposition process, leading to the deviations of the localized energy states from the regular positions or the average energy levels. Here, we suggest that control over such design factors in CQD solids can provide important pathways for improvements in device efficiencies as well as the charge carrier mobility. In particular, we have focused on the polydispersity in CQDs, which normally lies in the range of 5-15%. The effect of size-dispersion in CQD solids on the charge carrier mobility was computed using charge hopping transport models. The experimental film deposition processes were replicated using a molecular dynamics simulation where the equilibrium positions of CQDs with a given radii distribution were determined under a granular potential. The radii and positions of the CQDs were then used in the charge hopping transport simulator where the carrier mobility was estimated. We observed large decreases (up to 70%) in electron mobility for typical experimental polydispersity (about 10%) in CQD films. These large degradations in hopping charge transport were investigated using transport vector analysis with which we suggested that the site energy differences raised the portion of the off-axis rate of charge transport to the electric field direction. Furthermore, we have shown that controlling the size distribution remarkably impacts the charge carrier mobility and we suggested that tailored and potentially experimentally achievable re-arrangement of the CQD size ensemble can mediate the mobility drops even in highly dispersive cases, and presents an avenue towards improved charge transport. We then studied the degradation in CQD solar cells with respect to the polydispersity and how these enhanced charge transport from re-design of CQD solids can boost the photovoltaic performances. In addition, we estimated the potential in the binary CQD solids in terms of their improved charge transport and efficient light absorption. Combined with the accurate size-dependent optical absorption model for CQDs, our hopping model confirmed that the inclusion of smaller CQDs could enhance both the charge transport and the solar light absorption, leading to the enhanced average charge generation rates and solar cell performance.



Quantum Dot Heterojunction Solar Cells

Author : Rachelle Ihly

Publisher :

Page : 137 pages

File Size : 29,40 MB

Release : 2014

Category :

ISBN : 9781321207644

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This thesis explores the understanding of the chemistry and physics of colloidal quantum dots for practical solar energy photoconversion. Solar cell devices that make use of PbS quantum dots generally rely on constant and unchanged optical properties such that band gap energies remain tuned within the device. The design and development of unique experiments to ascertain mechanisms of optical band gap shifts occurring in PbS quantum dot thin-films exposed to air are discussed. The systematic study of the absorption properties of PbS quantum dot films exposed to air, heat, and UV illumination as a function of quantum dot size has been described. A method to improve the air-stability of films with atomic layer deposition of alumina is demonstrated. Encapsulation of quantum dot films using a protective layer of alumina results in quantum dot solids that maintain tuned absorption for 1000 hours. This thesis focuses on the use of atomic force microscopy and electrical variants thereof to study the physical and electrical characteristics of quantum dot arrays. These types of studies have broad implications in understanding charge transport mechanisms and solar cell device operation, with a particular emphasis on quantum dot transistors and solar cells. Imaging the channel potential of a PbSe quantum dot thin-film in a transistor showed a uniform distribution of charge coinciding with the transistor current voltage characteristics. In a second study, solar cell device operation of ZnO/PbS heterojunction solar cells was investigated by scanning active cross-sections with Kelvin probe microscopy as a function of applied bias, illumination and device architecture. This technique directly provides operating potential and electric field profiles to characterize drift and diffusion currents occurring in the device. SKPM established a field-free region occurring in the quantum dot layer, indicative of diffusion-limited transport. These results provide the path to optimization of future architectures that may employ drift-based transport in the quantum dot layer for enhanced charge extraction and power conversion efficiency.



Colloidal Quantum Dot Optoelectronics and Photovoltaics

Author : Gerasimos Konstantatos

Publisher : Cambridge University Press

Page : 329 pages

File Size : 21,44 MB

Release : 2013-11-07

Category : Science

ISBN : 0521198267

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Book Description

Captures the most up-to-date research in the field, written in an accessible style by the world's leading experts.





Colloidal Quantum Dot Optoelectronics and Photovoltaics

Author : Gerasimos Konstantatos

Publisher : Cambridge University Press

Page : 478 pages

File Size : 15,6 MB

Release : 2013-11-07

Category : Technology & Engineering

ISBN : 1107469368

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Book Description

Capturing the most up-to-date research in colloidal quantum dot (CQD) devices, this book is written in an accessible style by the world's leading experts. The application of CQDs in solar cells, photodetectors and light-emitting diodes (LEDs) has developed rapidly over recent years, promising to transform the future of clean energy, communications, and displays. This complete guide to the field provides researchers, students and practitioners alike with everything they need to understand these developments and begin contributing to future applications. Introductory chapters summarise the fundamental physics and chemistry, whilst later chapters review the developments that have propelled the field forwards, systematically working through key device advances. The science of CQD films is explained through the latest physical models of semiconductor transport, trapping and recombination, whilst the engineering of organic and inorganic multilayered materials is shown to have enabled major advances in the brightness and efficiency of CQD LEDs.





Nanocrystal Quantum Dots

Author : Victor I. Klimov

Publisher : CRC Press

Page : 485 pages

File Size : 38,11 MB

Release : 2017-12-19

Category : Technology & Engineering

ISBN : 1420079271

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Book Description

A review of recent advancements in colloidal nanocrystals and quantum-confined nanostructures, Nanocrystal Quantum Dots is the second edition of Semiconductor and Metal Nanocrystals: Synthesis and Electronic and Optical Properties, originally published in 2003. This new title reflects the book’s altered focus on semiconductor nanocrystals. Gathering contributions from leading researchers, this book contains new chapters on carrier multiplication (generation of multiexcitons by single photons), doping of semiconductor nanocrystals, and applications of nanocrystals in biology. Other updates include: New insights regarding the underlying mechanisms supporting colloidal nanocrystal growth A revised general overview of multiexciton phenomena, including spectral and dynamical signatures of multiexcitons in transient absorption and photoluminescence Analysis of nanocrystal-specific features of multiexciton recombination A review of the status of new field of carrier multiplication Expanded coverage of theory, covering the regime of high-charge densities New results on quantum dots of lead chalcogenides, with a focus studies of carrier multiplication and the latest results regarding Schottky junction solar cells Presents useful examples to illustrate applications of nanocrystals in biological labeling, imaging, and diagnostics The book also includes a review of recent progress made in biological applications of colloidal nanocrystals, as well as a comparative analysis of the advantages and limitations of techniques for preparing biocompatible quantum dots. The authors summarize the latest developments in the synthesis and understanding of magnetically doped semiconductor nanocrystals, and they present a detailed discussion of issues related to the synthesis, magneto-optics, and photoluminescence of doped colloidal nanocrystals as well. A valuable addition to the pantheon of literature in the field of nanoscience, this book presents pioneering research from experts whose work has led to the numerous advances of the past several years.



Designing Quantum Dot Solids for Optoelectronic Devices Through Matrix Engineering

Author : Jason Tolentino

Publisher :

Page : pages

File Size : 21,38 MB

Release : 2015

Category :

ISBN : 9781339124421

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Book Description

Colloidal quantum dot (CQD) solids represent a class of materials that allows one to control the optical and electronic properties due to their unique size-dependent properties with special electronic and optoelectronic device applications. Unfortunately, integration of these materials into high performing devices such as transistors and solar cells have been challenging due to: 1) uncontrolled environmental stability 2) lack of accurate control over charge carrier type and mobility 3) poor device operational stability and 4) limited experimental methods to probe the density of states in these materials in order to understand fundamental electronic and optical properties. In this thesis, we demonstrate the ability to stabilize and improve the environmental stability of these materials with amorphous Al2O3 (a-alumina). More importantly, we can accurately engineer the carrier type and mobility by varying the thickness of the alumina. Through a combination of small, compact inorganic ligands and the ability to passivate surface electronic traps, air-stable, high electron mobility PbSe QD field-effect transistors (FET) are obtained. We then show that we can also improve transistor device operational stability through an in-vacuo ligand exchange with H2S gas introduced in an atomic layer deposition (ALD) chamber. We find that this method is universal when volatile ligands are used. Possible mechanisms for device instability will be discussed such as proton migration and trap passivation. Using an optimized film preparation, this work will be the first demonstration of a QD FET with an electron mobility greater than 10 cm2 V-1 s-1 that is also operationally stable. Finally, we introduce a unique transmission spectroscopy technique of field-effect transistors to electrostatically probe induced charge carriers in PbSe QD films. With this technique we resolve occupation of quantized states of the quantum dots rather than the matrix or interfacial states. This platform is used to test fundamental transport models as it relates to disordered semiconductors such as QDs. From this technique, we can draw important conclusions about charge transport at room temperature. This novel experimental method can be extended to other experimental setups such as photoluminescence and photoconductivity in order to understand how to rationally improve the electronic properties of QD films.



Quantum Dot Solar Cells

Author : Jiang Wu

Publisher : Springer Science & Business Media

Page : 399 pages

File Size : 23,23 MB

Release : 2013-09-28

Category : Science

ISBN : 1461481481

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Book Description

The third generation of solar cells includes those based on semiconductor quantum dots. This sophisticated technology applies nanotechnology and quantum mechanics theory to enhance the performance of ordinary solar cells. Although a practical application of quantum dot solar cells has yet to be achieved, a large number of theoretical calculations and experimental studies have confirmed the potential for meeting the requirement for ultra-high conversion efficiency. In this book, high-profile scientists have contributed tutorial chapters that outline the methods used in and the results of various quantum dot solar cell designs, including quantum dot intermediate band solar cells, hot electron quantum dot solar cells, quantum-dot sensitized solar cells, colloidal quantum dot solar cells, hybrid polymer-quantum dot solar cells, and MEG quantum dot solar cells. Both theoretical and experimental approaches are described. Quantum Dot Solar Cells helps to connect the fundamental laws of physics and the chemistry of materials with advances in device design and performance. The book can be recommended for a broad audience of chemists, electrical engineers, and materials scientists, and is suitable for use in courses on materials and device design for advanced and future optoelectronics.



Colloidal Quantum Dots for Solar Energy Conversion

Author : Mengxia Liu

Publisher :

Page : 0 pages

File Size : 24,74 MB

Release : 2018

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ISBN :

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Book Description

Increasing global energy demand requires the development of clean energy sources that will help reduce the consumption of fossil fuels. Solar energy, the most abundant renewable source, is converted to electricity using photovoltaic devices. The photovoltaics market has witnessed rapid growth in the past decade, and today many photovoltaic strategies aim at low-cost, solution-processed manufacture. Colloidal quantum dots (CQDs), an emerging semiconductor material, have attracted attention in view of their spectral tunability. The bandgap of CQDs is readily tuned to harvest infrared solar energy. This could enable both full-spectrum devices and also tandem solar cells that can be integrated with wider-bandgap semiconductors. Unfortunately, a high density of surface-associated trap states, low carrier mobilities, and an inhomogeneous energy landscape have previously limited CQD photovoltaic performance. I introduce three strategies to address these problems. Through new materials processing approaches, I succeeded in increasing charge extraction, reducing bandtail states, and lowering the barrier to carrier hopping in CQD solids. The benefits from enhanced charge extraction were demonstrated in a double-sided junction architecture enabled by the engineering of an electron-accepting layer. This architecture resulted in an increase in the width of the carrier depletion region and a resultant decrease in recombination. I elucidated the effect of bandtail states on carrier transport and designed a solution-phase ligand-exchange method to create CQD inks that can be deposited as an active layer in a single step. The resulting CQD films exhibited a flattened energy landscape that increased the carrier diffusion length and contributed to solar cells having certified solar power conversion efficiencies of 11.3%. I then explored the translation of this strategy to small-bandgap infrared CQDs. Through management of surface ligands, I improved CQD passivation while reducing CQD fusion. I conclude with a new strategy for the design of a hybrid material system that combined CQDs with epitaxially-grown inorganic metal halide perovskites. The matrix-passivated CQD films showcased a two-fold increase in carrier mobility and superior thermal stability compared to pristine CQDs. This work provides promising pathways to achieve more fully the potential of CQD solids, and to showcase these advances in improved performance for CQD solar cells.