Nanoparticles — Publications
Inspired by the work of Nobel laureate Julian Schwinger, this book provides a clear, extensively illustrated introduction to quantum mechanics. It uses a combined approach of wave mechanics and spin analysis to explain the concepts of particle physics. The author’s pedagogical approach uses special process diagrams as tools for visualizing the states and operators as well as for illustrating ways to compute amplitudes for quantum mechanical processes. Problem sets build from the text and reinforce key principles. The first part of the book covers all the essential principles for the development of quantum mechanics. The second half focuses on quantum particles.
NSTI's nanotechnology conferences have built a tradition of being the most prestigious forum in the world for leading nano scientists, and Nanotech 2011 is no exception. Top nano scientists offer an up-to-date global perspective on the latest developments in nanotechnology. More than mere proceedings, these volumes cut across every scientific and engineering discipline to provide the most complete record of current accomplishments in Nanotech. Information from past conferences has been compiled into authoritative and comprehensive compendiums and made available (along with pricing information) here on our site. Contents of the proceedings for this year's conference and expo are provided here as well. Nanotech proceedings are available in print and on the TechConnect World 2011 Proceedings CD-ROM, which also includes Cleantech, Microtech, Bionanotech proceedings.
In the 1990s, nanoparticles and quantum dots began to be used in optical, electronic, and biological applications. Now they are being studied for use in solid-state quantum computation, tumor imaging, and photovoltaics. Handbook of Nanophysics: Nanoparticles and Quantum Dots focuses on the fundamental physics of these nanoscale materials and structures. Each peer-reviewed chapter contains a broad-based introduction and enhances understanding of the state-of-the-art scientific content through fundamental equations and illustrations, some in color.
This volume provides an overview of the major categories of nanoparticles, including amorphous, magnetic, ferroelectric, and zinc oxide nanoparticles; helium nanodroplets; and silicon, tetrapod-shaped semiconductor, magnetic ion-doped semiconductor, and natural polysaccharide nanocrystals. It also describes their properties and interactions. In the group of chapters on nanofluids, the expert contributors discuss the stability of nanodispersions, liquid slip at the molecular scale, thermophysical properties, and heat transfer. They go on to examine the theory, self-assembly, and teleportation of quantum dots.
Nanophysics brings together multiple disciplines to determine the structural, electronic, optical, and thermal behavior of nanomaterials; electrical and thermal conductivity; the forces between nanoscale objects; and the transition between classical and quantum behavior. Facilitating communication across many disciplines, this landmark publication encourages scientists with disparate interests to collaborate on interdisciplinary projects and incorporate the theory and methodology of other areas into their work.
Polymer latex particles continue to become increasingly important and numerous commercial applications. Advanced synthesis techniques are the key to developing new functionality for nanoparticles. These methods make it possible to tailor the size, chemical composition, or properties of these particles, as well as the molecular weight of the polymer chain as a whole, based on given requirements.
Advanced Polymer Nanoparticles: Synthesis and Surface Modifications summarizes important developments in the advanced synthesis and surface modification techniques to generate and mold polymer particles. This book explores the evolution and enhancement of processes such as emulsion, mini-emulsion, micro-emulsion, dispersion, suspension, inverse emulsion (in organic phase), and polymerization. Understanding these developments will enable the reader to optimize particle system design, giving rise to a greater application spectrum.
- Focuses on synthesis and characterization of particles with core-shell morphologies
- Details generation of nonspherical polymer particles using different synthetic routes
- Explores generation of specific architectures, such as block, star, graft, and gradient copolymer particles
The authors describe pH-responsive nanoparticles and smart, thermally responsive particles. They also cover surface tailoring of various organic and inorganic nanoparticles by polymers, as well as theoretical studies on the kinetics of controlled radical polymerization techniques. Condensing and evaluating current knowledge of the development of polymer nanoparticles, this reference will prove a valuable addition to the area of polymer latex technology.
Despite the widespread growth and acceptance of particulate technology, challenges in the design, operation, and manufacturing of these systems still exists. These critical issues must be resolved so that particle technology may continue to serve as a foundation for new nano and biotechnologies.
Nanoparticle Engineering for Chemical-Mechanical Planarization: Fabrication of Next-Generation Nanodevices
In the development of next-generation nanoscale devices, higher speed and lower power operation is the name of the game. Increasing reliance on mobile computers, mobile phone, and other electronic devices demands a greater degree of speed and power. As chemical mechanical planarization (CMP) progressively becomes perceived less as black art and more as a cutting-edge technology, it is emerging as the technology for achieving higher performance devices.
Over the last decade, the biggest advances in physical chemistry have come from thinking smaller. The leading edge in research pushes closer to the atomic frontier with every passing year. Collecting the latest developments in the science and engineering of finely dispersed particles and related systems, Finely Dispersed Particles: Micro-, Nano-, and Atto-Engineering explores heat, mass, momentum and electron transfer phenomena of well-characterized interfaces at the milli-, micro-, nano-, and atto-scales.
An interdisciplinary team of leading experts from around the world discuss recent concepts in the physics and chemistry of various well-studied interfaces of rigid and deformable particles in homo- and hetero-aggregate dispersed systems, including emulsions, dispersoids, foams, fluosols, polymer membranes, and biocolloids. The contributors clearly elucidate the hydrodynamic, electrodynamic, and thermodynamic instabilities that occur at interfaces, as well as the rheological properties of interfacial layers responsible for droplets, particles, and droplet-particle-film structures in finely dispersed systems. The book examines structure and dynamics from various angles, such as relativistic and non-relativistic theories, molecular orbital methods, and transient state theories.
With a comprehensive survey of our current understanding, Finely Dispersed Particles: Micro-, Nano-, and Atto-Engineering provides a solid platform for further exploration and discovery at increasingly smaller scales.
Since the advent of analytical techniques and capabilities to measure particle sizes in nanometer ranges, there has been tremendous interest in the use of nanoparticles for more efficient methods of drug delivery. This expertly written guide addresses the scientific methodologies, formulation, processing, applications, recent trends, and emerging technologies in the research of nanoparticulate drug delivery systems (NPDDS). It extensively covers applications of NPDDS, including lipid nanoparticles for dermal applications, nanocarriers for the treatment of restenosis, ocular, central nervous system, and gastrointestinal applications, and use as an adjuvant for vaccine development.
Nanoparticles, products of nanotechnology, are of increasing interest to the pharmaceutical community. They can increase drug solubility, enhance bioavailability, allow tissue targeting, offer decreased side-effects, and improve therapeutic efficacy.
Presenting the most pertinent and practical issues in the manufacturing and biological application of nanoparticles, this source presents state-of-the-art scientific contributions by seasoned authorities in the field.
Cubes, Triangular prisms, nano-acorn, nano-centipedes, nanoshells, nano-whiskers. . . .
Now that we can create nanoparticles in a wide variety of shapes and morphologies, comes the next challenge: finding ways to organize this collection of particles into larger and more complex systems.
Nanoparticle Assemblies and Superstructures, edited by pioneer of nanoparticle self-organization Nicholas A. Kotov, employs three critical questions to provide a framework of open-ended inquiry:
1. What are the methods of organization of nanocolloids in more complex structures
2. What kind of structures do we need
3. What are the new properties appearing in nanocolloid superstructures
Pulling together a collection of contributors unmatched in both their expertise and enthusiasm, Kotov presents what he refers to as a snapshot of nanoassembly work in progress. The first section of this comprehensive volume provides background through an assessment of the current status of nanoparticle assembly development and the requirements for different applications of organized nanomaterials. The middle chapters explore the changes that occur in various properties of individual particles when they are brought together to form agglomerates and simple assemblies. In the final section, a number of top scientists describe various methods for organizing particles in complex nanostructured superstructures. These include techniques involving biological ligands and force fields, as well as methods based on self-organization.
This remarkably prescient text upholds Kotov's belief that the research on organization of nanoparticles and other nanostructures, will most certainly uncover a wealth of "interesting discoveries and surprising phenomena."
Catalysis and Electrocatalysis at Nanoparticle Surfaces illustrates the latest developments in electrochemical nanotechnology, heterogeneous catalysis, surface science, and theoretical modeling. It describes the manipulation, characterization, control, and application of nanoparticles for enhanced catalytic activity and selectivity and presents a range of experimental and synthetic strategies for work in nanoscale surface science.
Thisis a comprehensive source for physical, surface, and colloid chemists; materials scientists; interfacial chemists and electrochemists; electrochemical engineers; theoretical physicists; chemical engineers; and upper-level undergraduate and graduate students in these disciplines.
Browse by Discipline