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MEng Materials Science & Engineering
About this course
Materials science and engineering investigates the fundamental relationships between the structure of matter at the atomic and microscopic scale and the properties that make different materials useful in engineering applications. It is a discipline that underpins nearly all manufacturing and technology, from the alloys in jet engines to the semiconductors in electronic devices, the polymers in medical implants and the ceramics in cutting tools. The University of Manchester is one of the world's leading centres for materials research, and this four-year full-time programme draws on that depth of expertise. The programme begins with a foundation year that ensures all students have a secure grounding in the scientific principles, mathematics and laboratory skills that the degree builds on, making it an excellent route for those whose prior study would benefit from this consolidation before the main degree content begins. From there you will move through the core science of crystallography, thermodynamics, phase diagrams and deformation behaviour before exploring the properties and processing of metals, polymers, ceramics and composites in detail. You will develop practical skills in characterisation techniques such as electron microscopy, diffraction and mechanical testing, and you will engage with the design of materials for specific engineering functions. Manchester's research environment means you are studying in a place where genuine advances in the field are being made, and the curriculum reflects that currency. The subject cultivates careful experimental thinking, the ability to move between scales of analysis and a habit of connecting physical observations to underlying theory. These are demanding but transferable intellectual skills. Graduates from materials science and engineering programmes are employed across aerospace, automotive, electronics, energy, biomedical devices, defence and advanced manufacturing. The degree supports progression towards chartered engineer status and provides an excellent foundation for postgraduate research in areas such as biomaterials, energy storage materials, structural alloys and nanomaterials.
Syllabus & Modules
Typical curriculumStudent Satisfaction
National Student Survey - 15 respondents (76% response rate)
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