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Full Description
The proposed book underscores the idea of harnessing the remarkable innovative designs of architected materials and structures observed in nature and integrating them into the field of engineering to design innovative materials, and structures with multifunctional properties targeting Defense, Automotive, Aerospace, Electronics, Nuclear, Healthcare, Energy, Sports, Packaging, Consumer Products etc. to offer improved safety, reliability, performance, durability, sustainability, and functionality. The proposed innovative materials, and structures draw inspiration from nature's designs and processes. This concept involves observing how living organisms have evolved solutions to various challenges over millions of years and applying these principles to design innovative materials and structures with multifunctional properties. This book reflects the understanding that nature has often provided elegant and efficient solutions to engineering challenges.
This book provides a thorough examination of the methods and techniques used in developing innovative materials, manufacturing process and structures, highlighting their potential for multifunctional applications. The book delves into the expansion of our understanding in this field, which is accompanied by novel synthesis, processing, and evaluation methods. These methods and techniques incorporate innovative strategies to create innovative high-performance materials and systems. These innovative materials and structures offer a wide range of properties and functions, making them highly attractive for various applications in different fields of advanced technology.
In today's rapidly evolving world, the development and utilization of innovative materials and structures for sustainable goals is gaining significant attention. With the increasing demand for improved materials with multiple functions, biomimetic and bioinspired approaches provide a promising avenue for the design and fabrication of high-performance innovative materials. By drawing inspiration from the intricate nano architectures and hierarchical structures found in biological materials, researchers are able to create innovative materials and structures that exhibit unique properties and functionalities. In addition, these materials can be tailored to have specific properties and functions, such as self-healing capabilities, high strength-to-weight ratios, enhanced fracture toughness, and failure tolerant which are the prime requirement for the researchers looking for innovative lightweight materials and structures.
