Author : Bong-Sub Lee
Publisher :
Page : pages
File Size : 37,5 MB
Release : 2006
Category :
ISBN :
Author : Simone Raoux
Publisher : Springer Science & Business Media
Page : 430 pages
File Size : 37,95 MB
Release : 2010-06-10
Category : Technology & Engineering
ISBN : 0387848746
"Phase Change Materials: Science and Applications" provides a unique introduction of this rapidly developing field. Clearly written and well-structured, this volume describes the material science of these fascinating materials from a theoretical and experimental perspective. Readers will find an in-depth description of their existing and potential applications in optical and solid state storage devices as well as reconfigurable logic applications. Researchers, graduate students and scientists with an interest in this field will find "Phase Change Materials" to be a valuable reference.
Author :
Publisher :
Page : 886 pages
File Size : 30,95 MB
Release : 2008
Category : Dissertations, Academic
ISBN :
Author : Alain Diebold
Publisher : Springer Nature
Page : 495 pages
File Size : 29,84 MB
Release : 2022-01-10
Category : Technology & Engineering
ISBN : 3030803236
This book covers the optical and electrical properties of nanoscale materials with an emphasis on how new and unique material properties result from the special nature of their electronic band structure. Beginning with a review of the optical and solid state physics needed for understanding optical and electrical properties, the book then introduces the electronic band structure of solids and discusses the effect of spin orbit coupling on the valence band, which is critical for understanding the optical properties of most nanoscale materials. Excitonic effects and excitons are also presented along with their effect on optical absorption. 2D materials, such as graphene and transition metal dichalcogenides, are host to unique electrical properties resulting from the electronic band structure. This book devotes significant attention to the optical and electrical properties of 2D and topological materials with an emphasis on optical measurements, electrical characterization of carrier transport, and a discussion of the electronic band structures using a tight binding approach. This book succinctly compiles useful fundamental and practical information from one of the fastest growing research topics in materials science and is thus an essential compendium for both students and researchers in this rapidly moving field.
Author : Hilmi Ünlü
Publisher : Springer Nature
Page : 939 pages
File Size : 31,92 MB
Release : 2022-10-18
Category : Technology & Engineering
ISBN : 3030934608
This book describes most recent progress in the properties, synthesis, characterization, modelling, and applications of nanomaterials and nanodevices. It begins with the review of the modelling of the structural, electronic and optical properties of low dimensional and nanoscale semiconductors, methodology of synthesis, and characterization of quantum dots and nanowires, with special attention towards Dirac materials, whose electrical conduction and sensing properties far exceed those of silicon-based materials, making them strong competitors. The contributed reviews presented in this book touch on broader issues associated with the environment, as well as energy production and storage, while highlighting important achievements in materials pertinent to the fields of biology and medicine, exhibiting an outstanding confluence of basic physical science with vital human endeavor. The subjects treated in this book are attractive to the broader readership of graduate and advanced undergraduate students in physics, chemistry, biology, and medicine, as well as in electrical, chemical, biological, and mechanical engineering. Seasoned researchers and experts from the semiconductor/device industry also greatly benefit from the book’s treatment of cutting-edge application studies.
Author : Hongjun Zheng
Publisher :
Page : pages
File Size : 25,65 MB
Release : 2019
Category :
ISBN :
ABSTRACTThe focus of my graduate research has been to study how size, composition, and structure, influence the optical-electronic properties of nanoscale systems. Towards this goal, I have utilized ultrafast time-resolved spectroscopy to study a series of monolayer protected clusters (MPCs) and plasmonic nanoparticles in order to elucidate carrier relaxation gold nano-systems in the hope of providing insight for improvement. As a first research accomplishment, I determined the transition size (~1.7 nm) between non-metallic and metallic electron behavior for gold nanoclusters. Having determined this characteristic transitional point, I divided subsequent research into three thrusts. The first was to expand the understanding of composition and structure domain dependence of carrier dynamics in ~1.7 nm size regime using ultrafast transient extinction spectroscopy. The second was to explore the ultrafast carrier dynamics in larger metallic nano-systems that are used widely in photo-driven applications. Primarily, my focus was to understand electron-electron scattering processes which relax in less than 500 fs. A fundamental understanding of this electron-electron scattering process is essential for understanding the quantum efficiency of utilizing the hot electrons. The last was to develop spatially resolved ultrafast spectroscopies in order to push our ability in studying structurally complicated systems such as layer materials which contain interesting optical-electronic properties but also have inherent heterogeneity problems that hinder the correlation of specific properties to the structure information. Explicitly, I developed spatially resolved two-dimensional electronic spectroscopy to fulfill this purpose.After the investigation of structure-dependent carrier relaxation dynamics at this transition point, the influence of structural modifications was characterized at the transition point. Specifically, the influence of Ag alloying on the relaxation pathways of the Au144(SR)60 cluster were studied. It was observed that the efficiency of electron-phonon coupling increased as a function of increasing silver alloying. These structure domain-dependent carrier dynamics studies were achieved by employing a state-selective pump-probe technique. Different vibration-assisted carrier relaxation channels were identified. In chapter 5, I demonstrate that excited carriers in Au144 cluster relax through three observable vibration-assisted channels, 2 THz, 1.44 THz, and 0.67 THz depends on where those carriers were located domain-dependent after excitation. These findings provided insight into carrier relaxation in the 144-atom gold cluster, and potential pathway in the modification of the carrier relaxation through structure engineer in MPCs.After the identification and characterization of the transitional point between metallic and nonmetallic nanoscale gold, two-dimensional electronic spectroscopy (2DES) was developed and utilized to study carrier relaxation in purely metallic systems. Here, plasmonic gold nanorods (NRs) were chosen as a model system of study. Leveraging the ultrafast time resolution and the ability to retrieve the homogeneous linewidth of the sample, I was able to determine the electron-electron scattering time constant to be around 150 fs for the NRs we studied. The process observed in Chapter 6 represents the build-up process of Fermi-Dirac distribution from athermal electron gas.Having observed the sensitive correlation between structural and electronic properties of nanoscale systems, I worked to develop a method designed to better directly probe structural influences. In chapter 7, I described the work of developing a spatially resolved two-dimensional electronic spectroscopy (sr-2DES), which facilitated our correlation of linear extinction and nonlinear sr-2DES signals. As a prototype experiment, thin films of aggregated CdSe nanocrystals were studied to demonstrate the combined spectral, temporal, and imaging capabilities of this method. The structural influence, i.e., the conjugation of the nanocrystal, was observed to result in a redshift of steady absorption and accelerated carrier relaxation dynamics.
Author :
Publisher :
Page : 17 pages
File Size : 34,51 MB
Release : 2011
Category :
ISBN :
Phase transformations are ubiquitous, fundamental phenomena that lie at the heart of many structural, optical and electronic properties in condensed matter physics and materials science. Many transformations, especially those occurring under extreme conditions such as rapid changes in the thermodynamic state, are controlled by poorly understood processes involving the nucleation and quenching of metastable phases. Typically these processes occur on time and length scales invisible to most experimental techniques (?s and faster, nm and smaller), so our understanding of the dynamics tends to be very limited and indirect, often relying on simulations combined with experimental study of the ''time infinity'' end state. Experimental techniques that can directly probe phase transformations on their proper time and length scales are therefore key to providing fundamental insights into the whole area of transformation physics and materials science. LLNL possesses a unique dynamic transmission electron microscope (DTEM) capable of taking images and diffraction patterns of laser-driven material processes with resolution measured in nanometers and nanoseconds. The DTEM has previously used time-resolved diffraction patterns to quantitatively study phase transformations that are orders of magnitude too fast for conventional in situ TEM. More recently the microscope has demonstrated the ability to directly image a reaction front moving at H"3 nm/ns and the nucleation of a new phase behind that front. Certain compound semiconductor phase change materials, such as Ge2Sb2Te5 (GST), Sb2Te and GeSb, exhibit a technologically important series of transformations on scales that fall neatly into the performance specifications of the DTEM. If a small portion of such material is heated above its melting point and then rapidly cooled, it quenches into an amorphous state. Heating again with a less intense pulse leads to recrystallization into a vacancy-stabilized metastable rock salt structure. Each transformation takes H"0-100 ns, and the cycle can be driven repeatedly a very large number of times with a nanosecond laser such as the DTEM's sample drive laser. These materials are widely used in optical storage devices such as rewritable CDs and DVDs, and they are also applied in a novel solid state memory technology - phase change memory (PCM). PCM has the potential to produce nonvolatile memory systems with high speed, extreme density, and very low power requirements. For PCM applications several materials properties are of great importance: the resistivities of both phases, the crystallization temperature, the melting point, the crystallization speed, reversibility (number of phase-transformation cycles without degradation) and stability against crystallization at elevated temperature. For a viable technology, all these properties need to have good scaling behavior, as dimensions of the memory cells will shrink with every generation. In this LDRD project, we used the unique single-shot nanosecond in situ experimentation capabilities of the DTEM to watch these transformations in GST on the time and length scales most relevant for device applications. Interpretation of the results was performed in conjunction with atomistic and finite-element computations. Samples were provided by collaborators at IBM and Stanford University. We observed, and measured the kinetics of, the amorphous-crystalline and melting-solidification transitions in uniform thin-film samples. Above a certain threshold, the crystal nucleation rate was found to be enormously high (with many nuclei appearing per cubic?m even after nanosecond-scale incubation times), in agreement with atomistic simulation and consistent with an extremely low nucleation barrier. We developed data reduction techniques based on principal component analysis (PCA), revealing the complex, multi-dimensional evolution of the material while suppressing noise and irrelevant information. Using a novel specimen geometry, we also achieved repeated switching between the amorphous and crystalline phases enabling in situ study of structural change after phase cycling, which is relevant to device performance. We also observed the coupling between the phase transformations and the evolution of morphology on the nanometer scale, revealing the gradual development of striations in uniform films and preferential melting at sharp edges in laser-heated nanopatterned GST. This nonuniform melting, interpreted through simulation as being a direct result of geometrical laser absorption effects, appears to be responsible for a marked loss in morphological stability even at moderate laser intensities and may be an important factor in the longevity of nanostructured phase change materials in memory applications.
Author : Kazuo Morigaki
Publisher : John Wiley & Sons
Page : 286 pages
File Size : 24,77 MB
Release : 2017-03-06
Category : Technology & Engineering
ISBN : 1118757920
Amorphous semiconductors are subtances in the amorphous solid state that have the properties of a semiconductor and which are either covalent or tetrahedrally bonded amorphous semiconductors or chelcogenide glasses. Developed from both a theoretical and experimental viewpoint Deals with, amongst others, preparation techniques, structural, optical and electronic properties, and light induced phenomena Explores different types of amorphous semiconductors including amorphous silicon, amorphous semiconducting oxides and chalcogenide glasses Applications include solar cells, thin film transistors, sensors, optical memory devices and flat screen devices including televisions
Author : National Research Council
Publisher : National Academies Press
Page : 238 pages
File Size : 37,49 MB
Release : 2003-03-19
Category : Science
ISBN : 0309168392
Chemistry and chemical engineering have changed significantly in the last decade. They have broadened their scopeâ€"into biology, nanotechnology, materials science, computation, and advanced methods of process systems engineering and controlâ€"so much that the programs in most chemistry and chemical engineering departments now barely resemble the classical notion of chemistry. Beyond the Molecular Frontier brings together research, discovery, and invention across the entire spectrum of the chemical sciencesâ€"from fundamental, molecular-level chemistry to large-scale chemical processing technology. This reflects the way the field has evolved, the synergy at universities between research and education in chemistry and chemical engineering, and the way chemists and chemical engineers work together in industry. The astonishing developments in science and engineering during the 20th century have made it possible to dream of new goals that might previously have been considered unthinkable. This book identifies the key opportunities and challenges for the chemical sciences, from basic research to societal needs and from terrorism defense to environmental protection, and it looks at the ways in which chemists and chemical engineers can work together to contribute to an improved future.
Author : Christopher Grieco
Publisher :
Page : pages
File Size : 34,43 MB
Release : 2017
Category :
ISBN :
Molecular packing arrangements at the nanoscale level significantly contribute to the ultimate photophysical properties of organic semiconducting materials used in solar energy conversion applications. Understanding their precise structure-function relationships will provide insights that can lead to chemical and structural design rules for the next generation of organic solar cell materials. In this work, two major classes of materials were investigated: Singlet fission sensitizers and semiconducting block-copolymers. By exploiting chemical design and film processing techniques, a variety of controllable nanoscale structures could be developed and related to their subsequent photophysical properties, including triplet and charge transport. Time-resolved optical spectroscopies, including both absorption and emission techniques, were used to measure the population dynamics of excited states and charge carriers following photoexcitation of the semiconducting materials. Singlet fission, an exciton multiplication reaction that promises to boost solar cell efficiency by overcoming thermalization loss, has been characterized in several organic molecules. If the energetics are such that the excited state singlet energy is at least twice the triplet energy, then a singlet exciton may split into two triplet excitons through an intermolecular energy-sharing process. The thin film structure of a model singlet fission compound was exploited by modulating its crystallinity and controlling polymorphism. A combination of visible, near-infrared, and mid-infrared transient absorption spectroscopies were used to investigate the precise singlet fission reaction mechanism. It was determined that the reaction intermediates consist of bound triplet pairs that must physically separate in order to complete the reaction, which results in multiplied, independent triplet excitations. Triplet transfer, which is modulated by molecular packing arrangements that control orbital overlap coupling, was found to determine the efficacy of triplet pair separation. Furthermore, the formation of these independent triplets was found to occur on longer (picosecond) timescales than previously believed, indicating that any kinetically competing relaxation processes, such as internal conversion, need to be controlled. Last, it was found that the diffusion of the multiplied triplet excitons, and thus their harvestability in devices, is highly influenced by the crystallinity of the material. In particular, the presence of even a small amount of contaminant amorphous phase was determined to be detrimental to the ultimate triplet diffusion length. Future research directions are outlined, which will be used to develop further chemical and structural design rules for the next generation of singlet fission chromophores. Semiconducting block-copolymers, because of their natural tendency to self-assemble into ordered nanoscale structures, offer an appealing strategy for controlling phase segregation between the hole and electron transport materials in organic solar cells. Such phase segregation is important for both ensuring efficient conversion of the photogenerated excitons into charge carriers, and for creating percolation pathways for efficient transport of the charges to the device electrodes. Time-resolved mid-infrared spectroscopy was developed for monitoring charge recombination kinetics in a series of block-copolymer and polymer blend films possessing distinct, controlled nanoscale morphologies. In addition to explaining previous work that correlated film structure to device efficiency, it was revealed how the covalent linkage in block-copolymers can be carefully designed to prevent rapid recombination losses. Furthermore, novel solution-phase systems of block-copolymer aggregates and nanoparticles were developed for future fundamental spectroscopic work. Future studies promise to explain precisely how polymer chain organization, including intrachain and interchain interactions, governs their ultimate charge photogeneration and transport properties in solar cells.
