Introduction to Materials Science - Volume 2

This second volume builds upon the foundation established in Volume 1, delving deeper into the practical applications of materials science principles in the context of nuclear facilities. It serves as an invaluable resource for engineers, scientists, and technical personnel involved in the design, operation, and maintenance facilities.

It assumes a basic understanding of the concepts covered in Volume 1 and expands on those concepts by providing detailed explanations of the practical considerations and applications of materials science.

Nonmetallic Materials: The handbook introduces the properties and applications of nonmetallic materials.

Corrosion and Degradation: The handbook examines the mechanisms of corrosion and degradation in metals and nonmetallic materials, emphasizing the factors that contribute to these processes in nuclear environments.

Material Selection and Applications: The handbook provides a comprehensive guide to material selection for various components and applications considering factors such as mechanical properties, corrosion resistance, radiation effects, and compatibility with other materials.

Material Testing and Evaluation: The handbook introduces various techniques for testing and evaluating materials, including mechanical testing, nondestructive testing, and radiation effects testing.

Material Design and Optimization: The handbook discusses the principles of material design and optimization, highlighting the role of materials science in developing advanced materials.

Volume 2 maintains the valuable features that enhance the handbook's effectiveness as a learning resource:

Practical Applications Focus: The handbook emphasizes the practical applications of materials science principles, making it relevant to the daily work of nuclear facility professionals.

Real-World Examples and Case Studies: The handbook incorporates real-world examples and case studies to illustrate the application of materials science principles in actual nuclear facilities.

References and Further Reading: The handbook provides extensive references and suggestions for further reading, enabling readers to delve deeper into specific topics.

Glossary of Terms: The handbook includes a comprehensive glossary of terms, providing clear definitions of key materials science concepts.

The Materials Science (Volume 2) stands as an essential guide for engineers, scientists, and technical personnel. Its emphasis on practical applications, real-world examples, and up-to-date information makes it an invaluable resource.Metal properties
Materials science
Mechanical properties
Physical properties
Thermal properties
Crystalline structure
Microstructure
Alloying elements
Heat treatment

Strength of metals
Ductility of metals
Toughness of metals
Hardness of metals
Fatigue of metals
Creep of metals
Corrosion of metals
Conductivity of metals
Magnetic properties of metals

Effect of microstructure on the properties of metals
Influence of alloying elements on the properties of metals
Relationship between heat treatment and the properties of metals
Applications of metal properties in engineering design
Material selection based on metal properties
Failure analysis of metals
Corrosion protection for metals
Heat treatment processes for metals
Alloying strategies for enhancing metal propertiesTensile strength
Yield strength
Elongation
Reduction in area
Fatigue life
Creep rupture time
Corrosion rate
Electrical conductivity
Thermal conductivity
Magnetic permeability

Structure of Metals
Properties of Metals
Thermal Shock
Brittle Fracture
Plant materials