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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.
Contents
Chapter 1. Advancing Sustainable Bioimplants: Innovative Tribological Performance of Laser-Textured and TiAlN-Coated Magnesium Alloys.- Chapter 2. Nano Silicon Carbide Enhanced Coconut Fiber Polymer Composites: Towards Stronger and Sustainable Materials.- Chapter 3. Enhancing Wear Resistance In Lightweight Al-Si-Sic Composites Through Molybdenum Disulfide.- Chapter 4. Advancing Green Concrete Technology: Performance Evaluation of Nano-Silica Enhanced Lightweight Mixes Using Pumice and LECA Aggregates.- Chapter 5. Mechanical Behavior of Sustainable AZ61-Based Hybrid Composite Materials.- Chapter 6. Optimization of Mechanical and Wear Properties of Epoxy Composites Reinforced with Abaca-Bamboo Hybrid Fibers.- Chapter 7. Innovative Approaches to Grain Refinement and Eutectic Modification in Aluminium-Silicon Alloys: A Comprehensive Review.- Chapter 8. Towards Lightweight and Sustainable Transportation: Role of Polymer Nanocomposites in Automotive Applications.- Chapter 9. High-Performance and Sustainable Alloy Design: A Review on Advanced Casting Simulation for Property Prediction.- Chapter 10. Mechanical Characterization of Sustainable GRP Composites Reinforced with Recycled Milled Glass.- Chapter 11. Enhancing Sustainable Composites: Mechanical Properties of Coir Fiber Reinforced Polyester with Titanium Filler.- Biofiller Integration.- Chapter 19. Nanoengineered Fiber Composites for Low-Velocity Impact Resistance and Advanced Functional Properties.- Chapter 20. Sustainable Energy Materials: Role of ZnO in Bio-Activated Carbon from Sweet Lime Peel for Supercapacitor Applications.- Chapter 21. Sustainable Energy Storage: Role of CrO₃ in Bio-Activated Carbon from Orange Peel for Supercapacitor Applications.- Chapter 22. Progress in Zn-Fluoroapatite (FAP) Composites for Biodegradable Orthopedic and Dental Applications.- Chapter 23. Enhanced Mechanical Properties of Aluminum Composites Reinforced with B₄C-TiC Particulates.- Chapter 24. Enhanced Mechanical Strength and Corrosion Resistance of Al7075 Hybrid Composites Reinforced with SiC and WC.- Chapter 25. Enhanced Strength and Toughness of Aluminum Composites Reinforced with SiC-B₄C-WC for Structural Applications.- Chapter 26. Mechanical and Wear Performance Enhancement of Stir-Cast Al6061 Hybrid Composites Reinforced with TiC and SiC.- Chapter 27. Innovative Processing Routes and Mechanical Performance of AZ61 Magnesium Alloys: A Comprehensive Review.- Chapter 28. Process Parameter Influence on Mechanical and Corro-sion Performance in Friction Stir Welding of 2024-T3 and 2198-T3 Aluminium Alloys.- Chapter 29. Influence of Tool Path Strategies on the Mechanical and Microstructural Behavior of AA6061-T6 in Friction Stir Welding.- Chapter 30. An Integrated Fuzzy Fmea-Qfd Framework For Developing Reliable And Efficient Laser Powder Bed Fusion 3d Metal Printers. Chapter 31. Sustainable Manufacturing Through Green Technology And Innovation: An Empirical Perspective.- Chapter 32. Multi-objective optimization of laser machining of SS304 sheet using desirability function analysis.- Chapter 33. Innovations in 4D Printing: Smart Polymers and Composites for Adaptive and Sustainable Applications.- Chapter 34. Process-Performance Correlation In Gas Tungsten Arc Welding Of Aisi 304hcu Tube Joints: An Empirical Approach.- Chapter 35. Enabling Circular Economy in Solar Energy: Innovative Analysis of EVA Removal Techniques.- Chapter 36. Sustainable Machining of Hybrid Natural Fiber -Reinforced Epoxy Composites Using Abrasive Waterjet Technology.- Chapter 37. Performance Analysis and Rotor Diameter Optimization of Concave-Bladed Hybrid Vertical Axis Wind Turbines at Ultra-Low Reynolds Numbers.- Chapter 38. Sustainable Wind Power Solutions: Optimized Hybrid Blade Design for Vertical Axis Wind Turbine Performance Improvement.- Chapter 39. Innovative Engine Technologies for Enhanced Performance, Combustion, and Emissions in Low Heat Rejection Engines.- Chapter 40. Performance Analysis of Eco-Friendly R152a Refrigerant Enhanced with CuO Nanofluids.- Chapter 41. Quantum Intelligence and AI for Next-Generation EV Ecosystems: Driving Sustainability, Efficiency, and Global Mobility.- Chapter 42. Next-Generation Technologies for Sustainable Manufacturing and Logistics: AI, Machine Learning, and Quantum Computing Perspectives.- Chapter 43. DESIGN AND ANALYSIS OF HYBRID COMPOSITE SPUR GEAR TEETH FOR LIGHT WEIGHT AND HIGH PERFORMANCE APPLICATIONS.- Chapter 44. Sustainable lightweight design: a short review on energy absorption in lightweight composite structures.- Chapter 45. Failure mechanisms and energy absorption behavior of 3D-printed composite lattice structures.- Chapter 46. Innovative Dual-Side Actuation Strategy for High-Performance Piezoelectric Energy Harvesting Systems.- Chapter 47. ADVANCED AUTOENCODER-BASED FRAMEWORKS FOR ROBUST ANOMALY DETECTION IN TIME SERIES DATA.- Chapter 48. Petri Net-Based Framework for Next-Generation Manufacturing: Enabling Industry 4.0 and Beyond.- Chapter 49. Future-Ready Manufacturing: The Impact of AI and Machine Learning on Industry 5.0.- Chapter 50. Energy-Sustainable Design of a Low-Power Bootstrapped Switch for High- Resolution SAR ADCs in 90nm CMOS Technology.- Chapter 51. Innovative Hydrokinetic Energy Solutions: A Comprehensive Review on Assessment, Design, and Optimization.- Chapter 52. Investigation of the Dynamic Behavior of Steel Plates Subjected to Underwater Impulse Loads.- Chapter 53. Sustainable Sound Energy Harvesting via PVDF Nanofibers Fabricated by Centrifugal Spinning.
