Microbeam Analysis Quantitative Analysis Using Energy Dispersive Spectrometry Eds For Elements With An Atomic Number Of 11 Na Or Above
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Microbeam Analysis. Quantitative Analysis Using Energy-Dispersive Spectrometry (EDS) for Elements with an Atomic Number of 11 (Na) Or Above
Chemical analysis and testing, Microanalysis, Quantitative analysis, Spectroscopy, Electron beams, Electron microscopes, Instrumental methods of analysis, X-rays
Metrology and Standardization for Nanotechnology
Author: Elisabeth Mansfield
language: en
Publisher: John Wiley & Sons
Release Date: 2017-04-10
For the promotion of global trading and the reduction of potential risks, the role of international standardization of nanotechnologies has become more and more important. This book gives an overview of the current status of nanotechnology including the importance of metrology and characterization at the nanoscale, international standardization of nanotechnology, and industrial innovation of nano-enabled products. First the field of nanometrology, nanomaterial standardization and nanomaterial innovation is introduced. Second, major concepts in analytical measurements are given in order to provide a basis for the reliable and reproducible characterization of nanomaterials. The role of standards organizations are presented and finally, an overview of risk management and the commercial impact of metrology and standardization for industrial innovations.
Computational Nanotoxicology
The development of computational methods that support human health and environmental risk assessment of engineered nanomaterials has attracted great interest because the application of these methods enables us to fill existing experimental data gaps. However, considering the high degree of complexity and multifunctionality of engineered nanoparticles, computational methods originally developed for regular (i.e., classic) chemicals cannot always be applied explicitly in nanotoxicology. Thus, the main idea of this book is to discuss the current state of the art and future needs in the development of computational modeling techniques for nanotoxicology. The book focuses on methodology. Among various in silico techniques, special attention is given to (i) computational chemistry (quantum mechanics, semi-empirical methods, density functional theory, molecular mechanics, molecular dynamics); (ii) nanochemoinformatic methods (quantitative structure–activity relationship modeling, grouping, read-across); and (iii) nanobioinformatic methods (genomics, transcriptomics, proteomics, metabolomics).