Multidirectional Functionally Graded Nanostructures
Modeling and Vibration Analysis
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Beschreibung
This book presents a detailed and application-oriented approach to modeling and vibration analysis of multidirectional Functionally Graded (FG) nanostructures using advanced analytical, semi-analytical, and numerical methods. To design more efficient and durable nanostructures used in applications such as sensors, micro-pumps, drug delivery systems, or underwater pipelines, scientists are now turning to a special class of materials called FG Materials. These materials are not uniform; rather, their properties change gradually across the structure. This book deals with nanostructures where these property variations occur not just in one direction, but in multiple directions, which is a more realistic and effective design strategy. The authors investigate how these tiny structures vibrate when exposed to dynamic environments using accurate mathematical models. Such analysis is key for preventing failure, improving sensitivity, and optimizing designs in high-performance nano-devices. The book implements advanced analytical, semi-analytical, and numerical techniques, offering high accuracy and computational efficiency in vibration analysis. The authors incorporate various nonlocal theories to accurately capture small-scale effects essential for nanoscale structures and also present comparative case studies and parametric analyses to facilitate a deeper understanding of how material gradation affects vibration behavior. In addition, the book provides both analytical formulations and MATLAB-based implementations, enabling readers to apply concepts in real-world scenarios. The book is tailored for researchers and engineers involved in designing and analyzing next-generation nanoscale systems and bridges the theoretical development of nonlocal theories with practical implementation strategies to support the design and optimization of nanoscale devices and structures in various engineering fields.
In addition, this book:
- Focuses exclusively on multidirectional FG nanostructures, addressing a crucial, but underexplored area in nanomechanics
- Blends material gradation, size-dependent effects, and structural vibration for accurate nano-device modeling and design
- Provides step-by-step mathematical derivations and covers a variety of boundary conditions and structural configurations
This book presents a detailed and application-oriented approach to modeling and vibration analysis of multidirectional Functionally Graded (FG) nanostructures using advanced analytical, semi-analytical, and numerical methods. To design more efficient and durable nanostructures used in applications such as sensors, micro-pumps, drug delivery systems, or underwater pipelines, scientists are now turning to a special class of materials called FG Materials. These materials are not uniform; rather, their properties change gradually across the structure. This book deals with nanostructures where these property variations occur not just in one direction, but in multiple directions, which is a more realistic and effective design strategy. The authors investigate how these tiny structures vibrate when exposed to dynamic environments using accurate mathematical models. Such analysis is key for preventing failure, improving sensitivity, and optimizing designs in high-performance nano-devices. The book implements advanced analytical, semi-analytical, and numerical techniques, offering high accuracy and computational efficiency in vibration analysis. The authors incorporate various nonlocal theories to accurately capture small-scale effects essential for nanoscale structures and also present comparative case studies and parametric analyses to facilitate a deeper understanding of how material gradation affects vibration behavior. In addition, the book provides both analytical formulations and MATLAB-based implementations, enabling readers to apply concepts in real-world scenarios. The book is tailored for researchers and engineers involved in designing and analyzing next-generation nanoscale systems and bridges the theoretical development of nonlocal theories with practical implementation strategies to support the design and optimization of nanoscale devices and structures in various engineering fields.
Focuses exclusively on multidirectional FG nanostructures, addressing a crucial, but underexplored area in nanomechanics Blends material gradation, size-dependent effects, and structural vibration for accurate nano-device modeling and design Provides step-by-step mathematical derivations and covers a variety of boundary conditions and structural configurations
Autor*in
Snehashish Chakraverty
Themen in »Multidirectional Functionally Graded Nanostructures«
Functionally Graded Materials Multidirectional Material Gradation Vibration Analysis of Nanobeams Nonlocal Theory Size-dependent Structural Modeling Advanced Nanostructure Mechanics Nanoscale Functionally Graded Materials Conventional FG Nanobeams Axially FG Nanobeams Free Vibration Analysis