Kirjahaku

Unique in its focus on functional properties, this book examines the resistive, piezoresistive, thermoelectric, and electromagnetic behavior of multifunctional cement-based materials for reduced cost, improved durability and maintenance, and optimization of various structural designs. The author analyzes cement-based compounds for enhancing a wide-range of structures, including buildings, bridges, highways, automobiles, and aircrafts, exploring characteristics such as vibration damping, strain sensing, electromagnetic and magnetic shielding, electrical conductivity, and thermal insulation for improved structure stability and performance.

Materials are the foundation of technology. As such, most universities provide engineering undergraduates with the fundamental concepts of materials science, including crystal structures, imperfections, phase diagrams, materials processing, and materials properties. Few, however, offer the practical, applications-oriented background that their students need to succeed in industry. Applied Materials Science: Applications of Engineering Materials in Structural, Electronics, Thermal, and Other Industries fills that gap. From a cross-disciplinary perspective that reflects both the multifunctionality of many materials and the wide scope industrial needs, the author examines the practical applications of metal, ceramic, polymer, cement, carbon, and composite materials across a broad range of industries. The topics addressed include electronic packaging, smart materials, thermal management, nondestructive evaluation, and materials development. The text is clear, coherent, and tutorial in style, includes numerous up-to-date references, and provides background material in a series of appendices. Unique in its breadth of coverage of both materials and their applications, Applied Materials Science is both scientifically rich and technologically relevant. If you work or teach those that aspire to work in an engineering capacity, you will find no text or reference that better prepares its readers for real-world applications of engineering materials.

Unique in its focus on functional properties, this book examines the resistive, piezoresistive, thermoelectric, and electromagnetic behavior of multifunctional cement-based materials for reduced cost, improved durability and maintenance, and optimization of various structural designs. The author analyzes cement-based compounds for enhancing a wide-range of structures, including buildings, bridges, highways, automobiles, and aircrafts, exploring characteristics such as vibration damping, strain sensing, electromagnetic and magnetic shielding, electrical conductivity, and thermal insulation for improved structure stability and performance.

Materials are the foundation of technology. As such, most universities provide engineering undergraduates with the fundamental concepts of materials science, including crystal structures, imperfections, phase diagrams, materials processing, and materials properties. Few, however, offer the practical, applications-oriented background that their students need to succeed in industry. Applied Materials Science: Applications of Engineering Materials in Structural, Electronics, Thermal, and Other Industries fills that gap. From a cross-disciplinary perspective that reflects both the multifunctionality of many materials and the wide scope industrial needs, the author examines the practical applications of metal, ceramic, polymer, cement, carbon, and composite materials across a broad range of industries. The topics addressed include electronic packaging, smart materials, thermal management, nondestructive evaluation, and materials development. The text is clear, coherent, and tutorial in style, includes numerous up-to-date references, and provides background material in a series of appendices. Unique in its breadth of coverage of both materials and their applications, Applied Materials Science is both scientifically rich and technologically relevant. If you work or teach those that aspire to work in an engineering capacity, you will find no text or reference that better prepares its readers for real-world applications of engineering materials.

The ?eld of composite materials has progressed greatly over the last few decades, as shown by the widespread use of ?brous composite - terials for airframes, sporting goods and other lightweight structures. Enabling this technological progress is scienti?c understanding of the design and mechanics of composite materials that involve continuous ?bers as the reinforcement. Current challenges in the ?eld of composite materials are associated with the extension of the ?eld of composite materials from structural composites to functional and multifunctional composites, the dev- opment of composite materials for electrical, thermal and other fu- tional applications that are relevant to current technological needs, and the improvement of composite materials through processing. Ex- ples of functions are joining (e. g. , brazing), repair, sensing, actuation, deicing (as needed for aircraft and bridges), energy conversion (as needed to generate clean energy), electrochemical electrodes, el- trical connection, thermal contact improvement and heat dissipation (i. e. , cooling, as needed for microelectronics and aircraft). Processing includes the use of additives (which may be introduced as liquids or solids), the combined use of ?llers (including discontinuous ones) at the micrometer and nanometer scales, the formation of hybrids (such as organic-inorganic hybrids), the modi?cation of the interfaces in a composite, and control over the microstructure. In other words, the development of composite materials for current technological needs must be application driven and process oriented. This is in contrast to the conventional composites engineering approach, which focuses on mechanics and purely structural applications.

The ?eld of composite materials has progressed greatly over the last few decades, as shown by the widespread use of ?brous composite - terials for airframes, sporting goods and other lightweight structures. Enabling this technological progress is scienti?c understanding of the design and mechanics of composite materials that involve continuous ?bers as the reinforcement. Current challenges in the ?eld of composite materials are associated with the extension of the ?eld of composite materials from structural composites to functional and multifunctional composites, the dev- opment of composite materials for electrical, thermal and other fu- tional applications that are relevant to current technological needs, and the improvement of composite materials through processing. Ex- ples of functions are joining (e. g. , brazing), repair, sensing, actuation, deicing (as needed for aircraft and bridges), energy conversion (as needed to generate clean energy), electrochemical electrodes, el- trical connection, thermal contact improvement and heat dissipation (i. e. , cooling, as needed for microelectronics and aircraft). Processing includes the use of additives (which may be introduced as liquids or solids), the combined use of ?llers (including discontinuous ones) at the micrometer and nanometer scales, the formation of hybrids (such as organic-inorganic hybrids), the modi?cation of the interfaces in a composite, and control over the microstructure. In other words, the development of composite materials for current technological needs must be application driven and process oriented. This is in contrast to the conventional composites engineering approach, which focuses on mechanics and purely structural applications.