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The engineer uses a wide variety of materials from platinum to rocks in order to construct bridges, automobiles, jet engines, process plants, electronic components, etc. These materials have widely varying properties and consequently it is necessary for the engineer to have a sound working knowledge of the characteristic properties and behaviour during processing/fabrication and in service of the common types of engineering materials. This course extends the basic course MEC1201 Engineering Materials, to show how the basic principles of materials science are used in the development of contemporary engineering materials used in everyday engineering applications.

This course is an advanced level materials engineering course, and builds onto prior engineering materials knowledge. The course design is primarily based on a case study that seeks to consolidate and assess higher-level analytical and critical thinking, but also seeks to introduce professional practice and judgement in applying various materials application methods. The relevant "materials science" content will be inherently explored through the case study, but the main emphasis will be on applications and practice. The objective here in this course is about getting student engineers to "think" rather than just "learn". This approach is demonstrated through systematic exploration, evaluation, synthesis, and application in material selection and failure analysis methods.

The course objectives define the student learning outcomes for a course. On completion of this course, students should be able to:

1. appraise the characteristics, properties, applications and behaviour (including strengthening mechanisms) during processing, fabrication and service of a wide range of engineering materials
2. examine and evaluate the effects of stress, fatigue, creep, corrosion, and wear on materials
3. examine and evaluate forms and effects of corrosion in metals and review the main methods of corrosion prevention
4. examine and evaluate the effects of welding on the properties of a welded component and the methods used to ensure a sound weld
5. systematically apply and justify the failure analysis of a material or a system of materials, including the use of relevant failure analysis methodologies
6. systematically specify and justify suitable material(s) for a given application, including the use of relevant material selection methodologies.