Engineering Research
Materials Science
Engineering Series
Books by Keyword: Electronic Materials
Books
The main aim of the 9-th Cross-Strait Conference on Engineering Materials (National Cheng Kung University, Tainan, Taiwan, 7-8 November, 2014) was presentation of fundamental studies, applied research and development and industrial applications of the different engineering materials including metals and alloys, materials for energy production, nanomaterials, environmental materials, biomaterials, polymeric materials, ceramics, electronic materials, and composites.
This is the volume for Part 2 including 122 papers selected from 12 symposia of AA. Multifunctional Composites and Meta-composites; G. Microelectronics and Optoelectronics Materials; H. Ferroelectric and Oxide Electronic Information Materials; I. Multiferroic Materials; J. Superhard Materials; K. Preparation and Application of Superconducting Material; L. Bulk Nano Ultra-fine Crystal Materials; M. Biomedical Materials; N. Advanced Ceramic Materials; O. Polymer Materials; P. Functional Elastomer Materials; Q. Shape Memory and Self-healing Polymeric Materials
The 86 papers are grouped as follows:
Chapter 1: Mathematical Theory and Numerical Methods;
Chapter 2: Materials Synthesis and Properties Research;
Chapter 3: Eco-Friendly and Biocompatible Materials;
Chapter 4: Nanomaterials - Synthesis and Application;
Chapter 5: Materials Manufacturing, Processing and Applications
The 79 papers are grouped as follows:
Chapter 1: Metallurgy;
Chapter 2: Steels and Alloys;
Chapter 3: Surface and Coating;
Chapter 4: Ceramics;
Chapter 5: Materials for Electronic and Electrical Industry;
Chapter 6: Polymers and Composites;
Chapter 7: Materials for Biomedical Application;
Chapter 8: Materials in Environmental Engineering and Construction;
Chapter 9: Materials and Technologies of Processing in Mechanical Engineering
The 69 papers are grouped as follows:
Chapter 1: Composites and Specialized Composites;
Chapter 2: Intelligent and Electronic Materials, Magnetic Materials;
Chapter 3: Optics and Solar Materials;
Chapter 4: Novel Researches on Machining and Processing of Materials;
Chapter 5: Synthesis and Characterization of Materials;
Chapter 6: Nanotechnologies: Nanofluids, Nanoribbon, Nano Thin Films;
Chapter 7: Researches on Materials Science and Technology
The 28 papers are grouped as follows:
Chapter 1: Function and Electronic Materials,
Chapter 2: High Performance Structural Material,
Chapter 3: Materials Processing Technology
The 126 papers are grouped as follows:
Chapter 1: Chemical Materials,
Chapter 2: Metal Materials and Alloys,
Chapter 3: Electronic Materials,
Chapter 4: Nano-Scale and Amorphous Materials,
Chapter 5: Biomaterials and Healthcare,
Chapter 6:Mechanical Materials and Engineering,
Chapter 7: Structural Materials and Civil Engineering,
Chapter 8: Environment Protection and Sustainable Development,
Chapter 9: Environmental Science and Engineering,
Chapter 10: Computation and Management Engineering Application
The 157 papers are grouped as follows:
Chapter 1: Nanofibers and Membranes,
Chapter 2: Nanoparticles and Powders,
Chapter 3: Thick and Thin Films,
Chapter 4: Biomaterials,
Chapter 5: Electronic Materials,
Chapter 6: Magnetic Materials,
Chapter 7: Optical Materials,
Chapter 8: Composites, Ceramics, and Alloys,
Chapter 9: Measurement and Characterization Techniques.
Volume is indexed by Thomson Reuters CPCI-S (WoS).
The topics of the 82 selected papers cover optical materials, electronic materials, electrical materials, magnetic materials, dielectric materials and optoelectronic devices. It provides a lot of useful information for ordinary readers as well as materials scientists and engineers who wish to understand the most recent development in the materials science field of semiconductors, dielectrics and optoelectronic devices.
The electronic properties of solids have become of increasing importance in the age of information technology. The study of solids and materials, while having originated from the disciplines of physics and chemistry, has evolved independently over the past few decades. The classical treatment of solid-state physics, which emphasized classifications, theories and fundamental physical principles, is no longer able to bridge the gap between materials advances and applications. In particular, the more recent developments in device physics and technology have not necessarily been driven by new concepts in physics or new materials, but rather by the ability of engineers to control crystal structures and properties better via advances in crystal growth and patterning techniques. In many cases, new applications simply arise from the adaption of conventional ideas to interdisciplinary areas. One example is that of recent advances which rely heavily upon the availability of the sub-micron technology developed by the semiconductor industry. Another example is the emergence of nanotechnology.