Materials Science: 10 Things Every Engineer Should Know

Start Date: 02/23/2020

Course Type: Common Course

Course Link: https://www.coursera.org/learn/materials-science

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About Course

We explore “10 things” that range from the menu of materials available to engineers in their profession to the many mechanical and electrical properties of materials important to their use in various engineering fields. We also discuss the principles behind the manufacturing of those materials. By the end of the course, you will be able to: * Recognize the important aspects of the materials used in modern engineering applications, * Explain the underlying principle of materials science: “structure leads to properties,” * Identify the role of thermally activated processes in many of these important “things” – as illustrated by the Arrhenius relationship. * Relate each of these topics to issues that have arisen (or potentially could arise) in your life and work. If you would like to explore the topic in more depth you may purchase Dr. Shackelford's Textbook: J.F. Shackelford, Introduction to Materials Science for Engineers, Eighth Edition, Pearson Prentice-Hall, Upper Saddle River, NJ, 2015

Course Syllabus

Welcome to week 1! In lesson one, you will learn to recognize the six categories of engineering materials through examples from everyday life, and we’ll discuss how the structure of those materials leads to their properties. Lesson two explores how point defects explain solid state diffusion. We will illustrate crystallography – the atomic-scale arrangement of atoms that we can see with the electron microscope. We will also describe the Arrhenius Relationship, and apply it to the number of vacancies in a crystal. We’ll finish by discussing how point defects facilitate solid state diffusion, and applying the Arrhenius Relationship to solid state diffusion.

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Course Introduction

Materials Science: 10 Things Every Engineer Should Know - Part 1 This course covers the 10 most important materials science principles, methods, and concepts, with special emphasis on materials used in buildings, materials processing, and materials management. This course is designed to provide an in-depth understanding of materials science, with the emphasis being on the 10 most important materials. This includes the fundamentals of atomic and molecular structure, bonding, bonding materials, materials properties, and selective application of analytical techniques to analyze properties of individual materials. In this course, we will begin by introducing a material science field, including atomic structure and bonding. We will then go in-depth with atomic structure and bonding in nature, with a focus on properties and properties of atomic bonds. We will then examine the methods used to design and select materials for specific applications. We will wrap up the course by looking at selected materials for analysis. Upon completing this course, you will be able to: 1. Describe the materials science field. 2. Select materials for analysis. 3. Design and select a material for analysis. 4. Analyze a material for properties and properties. 5. Design and select a material for a specific application. 6. Select a specific material for analysis. 7. Design a device for analysis. 8. Select a specific material for analysis. 9. Design a device for a specific application. 10. Select a specific material for analysis. Materials Science is one of the key topics in

Course Tag

Materials Mechanical Engineering Engineering Design Electrical Engineering

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