It provides basics of deformation and fracture in materials and the current state-of-the-art on experimental and numerical/theoretical methods including data driven approach in deformation and fracture study of materials. It is aimed at researchers and graduate students in fracture mechanics, finite element methods, and materials science.
It provides basics of deformation and fracture in materials and the current state-of-the-art on experimental and numerical/theoretical methods including data driven approach in deformation and fracture study of materials. It is aimed at researchers and graduate students in fracture mechanics, finite element methods, and materials science.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Anoop Kumar Mukhopadhyay, born in 1958, is currently Director, Research and Education at VCentMedia, Kolkata, and Director, Materials Research at a Kolkata Based Start Up. Dhaneshwar Mishra is currently working as Associate Professor at Department of Mechanical Engineering, Manipal University Jaipur, Rajasthan, India.
Inhaltsangabe
PART 1 Mechanics and Physics of Deformation and Fracture in Materials Chapter 1 Theoretical Approaches in Deformation and Fracture of Materials Chapter 2 The Physics of Deformation Behavior in Nanoindentation Studies of Materials Chapter 3 Applications of Machine Learning Techniques to Predict Behaviour of Materials PART 2 Experimental Methods to Study Mechanics and Physics of Deformation and Fracture in Materials Chapter 4 Deformation and Fracture of Metals: Experimental Methods and Challenges Chapter 5 Deformation and Fracture of Ceramic Materials: Experimental Methods and Challenges Chapter 6 Deformation and Fracture of Polymeric Materials: Experimental Methods and Challenges Chapter 7 Deformation and Fracture of Composite Materials: Experimental Methods and Challenges PART 3 Recent Advances in Modeling of Deformation and Fracture in Materials Chapter 8 Path-Independent Integrals and Their Applications in Fracture and Defect Mechanics Chapter 9 Modeling Crack Growth in Materials Using Finite Element Method Chapter 10 Nanoindentation Modeling of Materials Using Finite Element Method Chapter 11 FEM-Based Computational Studies on Impression Creep Behavior of Boron-Added P91 Steel Chapter 12 Channelling Deformation-Induced Electric Field Property of Polymer Hybrid Nanocomposite for Energy Harvesting Chapter 13 Atomistic Modelling and Molecular Dynamics Simulation for Elastic Deformation in Nanocomposites Chapter 14 Stress-Strain Response of Graphene-Reinforced Aluminium Composite: A Molecular Dynamics Study PART 4 Progress in Experimental Approaches Chapter 15 Physics of Deformation Behaviour in Nickel-Based Super Alloys Chapter 16 Nanoindentation Studies on Physics of Deformation at Microstructural Length Scale of Metals Chapter 17 Experimental Techniques to Study Physics of Deformation behavior in Glass at Microstructural Length Scale PART 5 Future Research Directions Chapter 18 Future Directions: Applications of Artificial Intelligence in Material Deformation and Fracture
PART 1 Mechanics and Physics of Deformation and Fracture in Materials Chapter 1 Theoretical Approaches in Deformation and Fracture of Materials Chapter 2 The Physics of Deformation Behavior in Nanoindentation Studies of Materials Chapter 3 Applications of Machine Learning Techniques to Predict Behaviour of Materials PART 2 Experimental Methods to Study Mechanics and Physics of Deformation and Fracture in Materials Chapter 4 Deformation and Fracture of Metals: Experimental Methods and Challenges Chapter 5 Deformation and Fracture of Ceramic Materials: Experimental Methods and Challenges Chapter 6 Deformation and Fracture of Polymeric Materials: Experimental Methods and Challenges Chapter 7 Deformation and Fracture of Composite Materials: Experimental Methods and Challenges PART 3 Recent Advances in Modeling of Deformation and Fracture in Materials Chapter 8 Path-Independent Integrals and Their Applications in Fracture and Defect Mechanics Chapter 9 Modeling Crack Growth in Materials Using Finite Element Method Chapter 10 Nanoindentation Modeling of Materials Using Finite Element Method Chapter 11 FEM-Based Computational Studies on Impression Creep Behavior of Boron-Added P91 Steel Chapter 12 Channelling Deformation-Induced Electric Field Property of Polymer Hybrid Nanocomposite for Energy Harvesting Chapter 13 Atomistic Modelling and Molecular Dynamics Simulation for Elastic Deformation in Nanocomposites Chapter 14 Stress-Strain Response of Graphene-Reinforced Aluminium Composite: A Molecular Dynamics Study PART 4 Progress in Experimental Approaches Chapter 15 Physics of Deformation Behaviour in Nickel-Based Super Alloys Chapter 16 Nanoindentation Studies on Physics of Deformation at Microstructural Length Scale of Metals Chapter 17 Experimental Techniques to Study Physics of Deformation behavior in Glass at Microstructural Length Scale PART 5 Future Research Directions Chapter 18 Future Directions: Applications of Artificial Intelligence in Material Deformation and Fracture
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