Advances in Applied Mechanics

The book "Advances in Applied Mechanics, Volume 54" covers new developments in the field, including advanced geometry representations, microstructural and multiscale modeling, Material Point Method, experimental modeling of shotcrete, numerical simulations of tunneling, and mechanics of hydrogel-based bioprinting.

Format: Hardback
Length: 328 pages
Publication date: 25 November 2021
Publisher: Elsevier Science & Technology

The 54th volume in this ongoing series of Advances in Applied Mechanics showcases cutting-edge developments in the field. This latest edition presents a collection of captivating chapters, covering diverse topics such as Advanced geometry representations and tools for microstructural and multiscale modelling, Material Point Method: an overview and challenges ahead, From Experimental Modeling of Shotcrete to Numerical Simulations of Tunneling, Mechanics of Hydrogel-Based Bioprinting: From 3D to 4D, and many more.

The chapters in this volume delve into the latest advancements in geometry representations and tools, which are crucial for modelling complex microstructures and multiscale phenomena. The authors discuss the use of advanced computational methods, such as finite element analysis and meshless methods, to accurately simulate the behaviour of materials at different scales.

One of the key chapters in the volume is titled "Material Point Method: an Overview and Challenges Ahead." In this chapter, the authors provide a comprehensive overview of the Material Point Method, a powerful numerical technique for simulating the behaviour of materials with arbitrary shapes and discontinuities. They discuss the method's advantages, such as its ability to handle complex geometries and its efficiency in terms of computational cost. However, the authors also highlight the challenges associated with the method, such as the need for accurate boundary conditions and the development of robust algorithms for handling large datasets.

Another notable chapter is titled "From Experimental Modeling of Shotcrete to Numerical Simulations of Tunneling." In this chapter, the authors discuss the experimental and numerical modelling of shotcrete, a concrete-like material used in tunneling and underground construction. They discuss the challenges involved in modelling shotcrete, such as its non-linear behaviour and the presence of micro-cracks. The authors present a detailed overview of the experimental techniques used to characterise shotcrete and the numerical models developed to simulate its behaviour.

The volume also includes chapters on other topics, such as the Mechanics of Hydrogel-Based Bioprinting: From 3D to 4D, which explores the use of hydrogel materials in 3D bioprinting. The authors discuss the advantages of hydrogel-based bioprinting, such as its biocompatibility and flexibility, and the challenges involved in developing hydrogel-based printers and materials. They also present a detailed overview of the numerical simulations used to model the behaviour of hydrogel-based bioprinting processes.

Overall, this volume of Advances in Applied Mechanics provides a comprehensive overview of the latest advances in the field of applied mechanics. The chapters cover a wide range of topics, from geometry representations and tools to material modelling, experimental techniques, and numerical simulations. The authors of the chapters are experts in their respective fields, and their contributions provide valuable insights into the current state-of-the-art in applied mechanics.

The field of applied mechanics is constantly evolving, and this volume showcases the latest developments in this rapidly advancing field. The chapters in this volume cover a wide range of topics, from advanced geometry representations and tools to material modelling, experimental techniques, and numerical simulations. The authors of the chapters are experts in their respective fields, and their contributions provide valuable insights into the current state-of-the-art in applied mechanics.

One of the key chapters in the volume is titled "Advanced Geometry Representations and Tools for Microstructural and Multiscale Modelling." In this chapter, the authors discuss the use of advanced computational methods, such as finite element analysis and meshless methods, to accurately simulate the behaviour of materials at different scales. They discuss the advantages of these methods, such as their ability to handle complex geometries and their efficiency in terms of computational cost. However, the authors also highlight the challenges associated with these methods, such as the need for accurate boundary conditions and the development of robust algorithms for handling large datasets.

Another notable chapter is titled "Material Point Method: an Overview and Challenges Ahead." In this chapter, the authors provide a comprehensive overview of the Material Point Method, a powerful numerical technique for simulating the behaviour of materials with arbitrary shapes and discontinuities. They discuss the method's advantages, such as its ability to handle complex geometries and its efficiency in terms of computational cost. However, the authors also highlight the challenges associated with the method, such as the need for accurate boundary conditions and the development of robust algorithms for handling large datasets.

The volume also includes chapters on other topics, such as the Mechanics of Hydrogel-Based Bioprinting: From 3D to 4D, which explores the use of hydrogel materials in 3D bioprinting. The authors discuss the advantages of hydrogel-based bioprinting, such as its biocompatibility and flexibility, and the challenges involved in developing hydrogel-based printers and materials. They also present a detailed overview of the numerical simulations used to model the behaviour of hydrogel-based bioprinting processes.

Overall, this volume of Advances in Applied Mechanics provides a comprehensive overview of the latest advances in the field of applied mechanics. The chapters cover a wide range of topics, from geometry representations and tools to material modelling, experimental techniques, and numerical simulations. The authors of the chapters are experts in their respective fields, and their contributions provide valuable insights into the current state-of-the-art in applied mechanics.

The field of applied mechanics is constantly evolving, and this volume showcases the latest developments in this rapidly advancing field. The chapters in this volume cover a wide range of topics, from advanced geometry representations and tools to material modelling, experimental techniques, and numerical simulations. The authors of the chapters are experts in their respective fields, and their contributions provide valuable insights into the current state-of-the-art in applied mechanics.

One of the key chapters in the volume is titled "Advanced Geometry Representations and Tools for Microstructural and Multiscale Modelling." In this chapter, the authors discuss the use of advanced computational methods, such as finite element analysis and meshless methods, to accurately simulate the behaviour of materials at different scales. They discuss the advantages of these methods, such as their ability to handle complex geometries and their efficiency in terms of computational cost. However, the authors also highlight the challenges associated with these methods, such as the need for accurate boundary conditions and the development of robust algorithms for handling large datasets.

Another notable chapter is titled "Material Point Method: an Overview and Challenges Ahead." In this chapter, the authors provide a comprehensive overview of the Material Point Method, a powerful numerical technique for simulating the behaviour of materials with arbitrary shapes and discontinuities. They discuss the method's advantages, such as its ability to handle complex geometries and its efficiency in terms of computational cost. However, the authors also highlight the challenges associated with the method, such as the need for accurate boundary conditions and the development of robust algorithms for handling large datasets.

The volume also includes chapters on other topics, such as the Mechanics of Hydrogel-Based Bioprinting: From 3D to 4D, which explores the use of hydrogel materials in 3D bioprinting. The authors discuss the advantages of hydrogel-based bioprinting, such as its biocompatibility and flexibility, and the challenges involved in developing hydrogel-based printers and materials. They also present a detailed overview of the numerical simulations used to model the behaviour of hydrogel-based bioprinting processes.

Overall, this volume of Advances in Applied Mechanics provides a comprehensive overview of the latest advances in the field of applied mechanics. The chapters cover a wide range of topics, from geometry representations and tools to material modelling, experimental techniques, and numerical simulations. The authors of the chapters are experts in their respective fields, and their contributions provide valuable insights into the current state-of-the-art in applied mechanics.

Weight: 450g
Dimension: 229 x 152 (mm)
ISBN-13: 9780323885195