Cryo-TEM of Morphology and Kinetics of Self-assembled Nanostructures
Author: Jingshan Dong
Publisher:
Published: 2006
Total Pages: 476
ISBN-13:
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Self-Organized Morphology in Nanostructured Materials
Author: Katharina Al-Shamery
Publisher: Springer Science & Business Media
Published: 2007-12-27
Total Pages: 182
ISBN-13: 3540726756
DOWNLOAD EBOOKIntegrating nano and microphysical effects, this book’s team of expert authors offers new insights into self-organized structure formation in nanomaterials. A major question addressed in this book is the role of spatial and temporal order. In particular, you’ll discover how to apply concepts developed on macroscopic and microscopic scales to structure formation occurring on nanoscales, a key focus of interest at the frontiers of science.
Engineering the Kinetics of Self Assembly of Faceted Nanoparticles
Author: Abhishek Kumar Sharma
Publisher:
Published: 2021
Total Pages: 0
ISBN-13:
DOWNLOAD EBOOKRecent developments in synthesis techniques have enabled production of colloidal nanoparticles of with intricate shapes with unprecedented precision. When put under high osmotic pressure, faceted particles can self-assemble into intricate structures that find applications in photonic and photoelectric systems. Thus, it is of engineering interest to understand design principles governing nanoparticle self-assembly. Not only can such understanding be of practical importance, but it can also reveal general principles about the way how naturally occurring systems self-assemble into complex nanostructures. In this thesis, I will discuss findings from our Monte Carlo simulations that reveal the influence of the shape of a nanoparticle on its self-assembly. We find that the way such nanoparticles are faceted has important consequences upon how quickly they self-assemble, providing us 'design rules' for the nanoparticle shape. For example, octahedral particles tend to align their facets in the disordered phase, but not in the ordered phase. Entropic preference to facet alignment in the disordered phase results in a large kinetic barrier for its disorder-order transition. In our studies of a variety of shapes (such as cubes, truncated cubes and gyrobifastigia), we have found transitions that show departures from classical nucleation that motivate development of new theories and simulation methods. Based on the geometric properties of the particle shape, such particles may also form mesophases - phases that have an intermediate degree of order between disordered and ordered phases. I will also illustrate examples of transitions to and from mesophases - and how their existence might hinder or accelerate disorder to order transitions. We studied how either a rotator mesophase or a liquid crystal forms a crystal; the former case illustrates a transition primarily involving particle reorientations with minimal translations, while the latter is an example of a transition with large particle translations with minimal reorientations. In both cases, we the structure and formation kinetics of the incipient crystalline nucleus could depart from the classical theory considerably. These results contribute to improving our current understanding of self-assembly of nanoparticles, with predictions that are suitable for experimental validation in near future.
Engineering Self-assembled Nanostructures with Externally Applied Fields
Author: Dongchoul Kim
Publisher:
Published: 2006
Total Pages: 284
ISBN-13:
DOWNLOAD EBOOKSelf-Assembled Nanostructures Formation in Hybrid Metal-Mesogenic Systems
Author: Tatyana Shabatina
Publisher:
Published: 2019
Total Pages: 0
ISBN-13:
DOWNLOAD EBOOKThis chapter reviews the methods of supramolecular chemistry and cryochemistry to study the formation, morphological and structural properties, and possible applications of hybrid nanostructures and nanosized aggregates comprising plasmonic metals (silver and copper) and several mesogenic compounds, which exhibit different liquid crystalline mesophases,Äînematics, smectics, and cholesterics. Low-temperature vacuum co-condensation of reagent vapors on cooled surfaces of quartz, KBr, CaF2, or polished copper was used to synthesize hybrid nanosystems including silver and copper and long-chain mesogenic derivatives of alkylcyanobiphenyls under molecular beam conditions. Controlled thermal treatment of the samples allowed the directed formation of metal nanoparticles of definite size from 2 up to 100¬†nm. It was shown that the procedures of temperature treatments and molecular self-organization of different liquid crystalline phases controlled the size and morphology of nanoparticles and their aggregates, which were formed in the system. Transmission electron microscopy (TEM) and atomic force microscopy (AFM) data of the samples show the formation of orientationally ordered structures in nematic mesophases. Formation of flat 2D aggregates was found in layered smectic mesophases. Optical absorbance spectra of silver/4-pentyl-4-cyanobiphenyl (Ag/5-°-í) and copper/4-pentyl-4-cyanobiphenyl (Cu/5CB) samples encapsulated in polymer poly-para-xylylene at 300¬†K contained characteristic bands of plasmonic absorbance of metal nanoparticles at 420,Äì440¬†nm and 560,Äì600¬†nm. Rising metal concentration in the sample led to the performable growth of rod-like metal particles with anisometric ratio l/d¬†>¬†20 and intensive absorbance at higher wavelengths (Œa¬†,╬†650¬†nm). New hybrid nanosystems based on biomolecules of cholesterol or its heteroatomic analog thiocholesterol including nanosized silver particles of d¬†=¬†5.0¬†¬±¬†0.5 and d¬†=¬†2.5¬†¬±¬†0.5¬†nm, respectively, were obtained. Highly ordered 1D-, 2D-, and 3D structures containing silver nanoparticles were formed from concentrated organic sols at different support surfaces by removing the inert solvent from triple metal/ligand/solvent system and by cooling the binary metal/ligand system from isotropic state to the cholesteric liquid crystalline mesophase. The microstructure and composition of the hybrid nanosystems were characterized by FTIR, UV-Vis spectroscopy, TEM, and selected area electron diffraction (SAED). It was shown that hybrid nanosystems based on silver nanoparticles covered by a stabilizing layer of mesogenic molecules of thiocholesterol display selectivity in adsorption of optical isomers of the selected compounds.
Artificial Protein and Peptide Nanofibers
Author: Gang Wei
Publisher: Woodhead Publishing
Published: 2020-07-28
Total Pages: 504
ISBN-13: 0081028512
DOWNLOAD EBOOKArtificial Protein and Peptide Nanofibers: Design, Fabrication, Characterization, and Applications provides comprehensive knowledge of the preparation, modification and applications of protein and peptide nanofibers. The book reviews the synthesis and strategies necessary to create protein and peptide nanofibers, such as self-assembly (including supramolecular assembly), electrospinning, template synthesis, and enzymatic synthesis. Then, the key chemical modification and molecular design methods are highlighted that can be utilized to improve the bio-functions of these synthetic fibers. Finally, fabrication methods for key applications, such as sensing, drug delivery, imaging, tissue engineering and electronic devices are reviewed. This book will be an ideal resource for those working in materials science, polymer science, chemical engineering, nanotechnology and biomedicine. - Reviews key chemical modification and molecular design methods to improve the bio-functions of synthetic peptide and protein nanofibers - Discusses the most important synthesis strategies, including supramolecular assembly, electrospinning, template synthesis and enzymatic synthesis - Provides information on fabrication of nanofibers for key applications such as sensing, imaging, drug delivery and tissue engineering
Self-Assembled Nanostructures
Author: Jin Zhang
Publisher: Springer
Published: 2014-01-15
Total Pages: 340
ISBN-13: 9781475787238
DOWNLOAD EBOOKNanostructures refer to materials that have relevant dimensions on the nanometer length scales and reside in the mesoscopic regime between isolated atoms and molecules in bulk matter. These materials have unique physical properties that are distinctly different from bulk materials. Self-Assembled Nanostructures provides systematic coverage of basic nanomaterials science including materials assembly and synthesis, characterization, and application. Suitable for both beginners and experts, it balances the chemistry aspects of nanomaterials with physical principles. It also highlights nanomaterial-based architectures including assembled or self-assembled systems. Filled with in-depth discussion of important applications of nano-architectures as well as potential applications ranging from physical to chemical and biological systems, Self-Assembled Nanostructures is the essential reference or text for scientists involved with nanostructures.
Simulation and Control of Dynamic Directed Self-assembly of Nanostructures
Author: Sivaraman Ramaswamy
Publisher:
Published: 2015
Total Pages: 117
ISBN-13:
DOWNLOAD EBOOKSelf-assembled nanoscale structures are the basis for various technological advancements in functional materials, sensors, and molecular circuits and factories. With significant progress in self-assembly of periodic nanostructures (such as monolayers), the focus is now shifting towards non-periodic structures. Control of various interaction force fields (electrostatic, Van der Waals, etc.) between the nanoparticles and external controls can result in the formation of nanostructures with desired geometry. The aim is to design the nanoparticles and the external actuators such that the desired structure can be self-assembled rapidly with high reliability and avoiding any kinetic trapping that an ill-designed energy landscape might cause. Deterministic dynamic modeling of such self-assembled nanostructures, directed by external fields, through a Master Equation approach, leads to a set of differential equations of such large size that even the most efficient solution algorithms are overwhelmed. Thus, model reduction is a key necessity. This thesis presents a methodological approach and specific algorithms, which generate time-varying, reduced-order models for the description of directed self-assembly of nanoparticles by external fields. The approach is based on Finite State Projection and is adaptive, i.e., it generates reduced-order models that vary over time. The algorithm uses event-detection concepts to determine automatically, during simulation, suitable time points at which the projection space and thus the structure of the reduced-order model change, in such a way that the computational load remains low while the upper bound on the simulation error, resulting from model reduction, is lower than a prescribed maximum limit. The thesis also presents an optimal control strategy that can guide any initial random configuration of nanoparticles to a final structure of desired geometry, in minimum time. It employs a multi-resolution view of the dynamically evolving configurations of nanoparticles, which are described through the simulation methodology described before. External charges, attracting or repelling the nanoparticles, are the controls, whose location and intensity are determined by the optimality conditions of the optimal control strategy. To ensure analytic consistency of the parametric sensitivities, during the computation of the optimal controls, and thus guarantee the optimality of the resulting control policy, a priori determination of enlarged constant projection spaces is shown to be essential. The thesis also presents a series of case studies, which illustrate how the proposed methods can be used to simulate effectively directed self-assembly of an appreciable number of nanoparticles, and reach the desired geometry. These case studies also illuminate several of its features, such as: superiority over a static optimal solution; evasion of kinetic traps; and effective handling of combinatorial complications arising for systems with large-size domains and many particles.
Self-Assembly of Nanostructures
Author: Stefano Bellucci
Publisher: Springer
Published: 2011-10-26
Total Pages: 268
ISBN-13: 9781461407430
DOWNLOAD EBOOKThis is the third volume in a series of books on selected topics in Nanoscale Science and Technology based on lectures given at the well-known Istituto Nazionale di Fisica Nucleare (INFN) schools of the same name. The present set of notes stems in particular from the participation and dedication of prestigious lecturers, such as Nunzio Motta, Fulvia Patella, Alexandr Toropov, and Anna Sgarlata. All lectures have been carefully edited and reworked, taking into account extensive follow-up discussions. A tutorial lecture by Motta et al. presents the analysis of the Poly(3-hexylthiophene) self assembly on carbon nanotubes and discusses how the interaction between the two materials forms a new hybrid nanostructure, with potential application to future solar cells technology. In their contribution, Patella et al. review quantum dots of III-V compounds, which offer appealing perspectives for more sophisticated applications in new generation devices such as single-photon emitters for nano-photonics and quantum computing. Focusing on self-assembled quantum dots, the chapter by Alexandr Toropov et al. provides a comprehensive review of some important aspects in the formation of quantum dots and presents the results of the authors’ extensive investigation of the features of droplet epitaxy. The fourth contribution, by Sgarlata et al., focuses on recent progress toward controlled growth of self-assembled nanostructures, dealing with the shaping, ordering and localization in Ge/Si heteroepitaxy and reviewing recent results on the self-organization of Ge nanostructures at Si surfaces.
Templated Self Assemble of Nano-Structures
Author:
Publisher:
Published: 2013
Total Pages:
ISBN-13:
DOWNLOAD EBOOKThis project will identify and model mechanisms that template the self-assembly of nanostructures. We focus on a class of systems involving a two-phase monolayer of molecules adsorbed on a solid surface. At a suitably elevated temperature, the molecules diffuse on the surface to reduce the combined free energy of mixing, phase boundary, elastic field, and electrostatic field. With no template, the phases may form a pattern of stripes or disks. The feature size is on the order of 1-100 nm, selected to compromise the phase boundary energy and the long-range elastic or electrostatic interaction. Both experimental observations and our theoretical simulations have shown that the pattern resembles a periodic lattice, but has abundant imperfections. To form a perfect periodic pattern, or a designed aperiodic pattern, one must introduce a template to guide the assembly. For example, a coarse-scale pattern, lithographically defined on the substrate, will guide the assembly of the nanoscale pattern. As another example, if the molecules on the substrate surface carry strong electric dipoles, a charged object, placed in the space above the monolayer, will guide the assembly of the molecular dipoles. In particular, the charged object can be a mask with a designed nanoscale topographic pattern. A serial process (e.g., e-beam lithography) is necessary to make the mask, but the pattern transfer to the molecules on the substrate is a parallel process. The technique is potentially a high throughput, low cost process to pattern a monolayer. The monolayer pattern itself may serve as a template to fabricate a functional structure. This project will model fundamental aspects of these processes, including thermodynamics and kinetics of self-assembly, templated self-assembly, and self-assembly on unconventional substrates. It is envisioned that the theory will not only explain the available experimental observations, but also motivate new experiments.
