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Materials Science×

University of Manchester, Full Time Masters Degrees in Materials Science

We have 24 University of Manchester, Full Time Masters Degrees in Materials Science

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The masters course in Polymer Materials Science and Engineering, offered in partnership with the School of Chemistry, is multi-disciplinary. Read more
The masters course in Polymer Materials Science and Engineering, offered in partnership with the School of Chemistry, is multi-disciplinary: it provides Chemists, Materials Scientists and Engineers with a rich understanding of both traditional commodity plastics and speciality polymers with increasing applications in the biomedical and pharmaceutical fields, and in electronics and nanotechnology. The full range of issues, from fundamental polymer science, through polymer processing, to manufacturing are all covered.

Career opportunities

The majority of graduates of this programme go on to fill key posts as materials scientists, engineers, managers and consultants in academia, industry and research and development. Some advance to PhD programmes within the School.

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Due to the high volume of applications, this course is now over-subscribed. Applications for this course can still be made, and successful applicants will be added to a waiting list. Read more
Due to the high volume of applications, this course is now over-subscribed. Applications for this course can still be made, and successful applicants will be added to a waiting list. Places will be allocated from the waiting list on a first-come, first-served basis should places become available.

Please note, having a space on the waiting list is not a guarantee of an offer.

Aims

The programme aims to convey detailed knowledge of state-of-the-art materials systems, with a focus on composites, advanced alloys and functional and engineering ceramics. The students explore the technologies used in the manufacture and processing of advanced materials and develop an understanding of the relationships between composition, microstructure, processing and performance. The student learn how to assess materials performance in service and develop an understanding of the processes of degradation in hostile conditions. They are also trained in the essential skills needed to design and develop the next generation of high performance engineering materials, establishing a strong foundation for a future career in industry or research.

Course unit details

The taught units cover the structure and design of advanced engineering materials and provide graduates with an increased depth and breadth of knowledge of materials science, technology and engineering.

Taught units include:
-Introduction to Materials Science
-Industrial Processing of Materials
-Advanced Composite Materials
-High Performance Alloys
-Advanced Analytical Techniques
-Functional and Engineering Ceramics

Facilities

To underpin the research and teaching activities at the School, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Career opportunities

Our graduates of this programme have gone on to fill key posts as materials scientists, engineers, managers and consultants in academia, industry and research and development. You may also be able to advance to PhD programmes within the School.

Accrediting organisations

The MSc in Advanced Engineering Materials is accredited by the Institute of Materials, Minerals and Mining (IoM3) with the award of Further Learning.

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Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance. Read more
Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance.

Research Focus

The research extends from fundamental science, and the `blue skies' development of novel technologies and techniques, to the very applied, with the aim of improving our understanding of the basic governing principles, process simulation and physical modelling. While our research is broad ranging, we focus on light alloys for aerospace and transport applications, high-temperature materials for aeroengines and power generation, and metal composites, as well as the failure of metallic materials, their environmental degradation and surface treatment. The research is supported by state of the art equipment for materials characterisation, testing, simulation and processing.

Examples of recent student PhD projects include; Microstructure Modelling for Friction Stir Welding, Laser Surface treatment of Aerospace Alloys, Advanced Strain Mapping for Structural Integrity application, Dynamic Grain Growth in Super Plastic Forming, Dynamics and Morphology of Stress Corrosion Cracking Using 3D X-ray Tomography, and Laser Depositioning of Nickel Base Superalloys.

Industry links

We have strong links with industry and the funding councils and sponsorship from global companies, including; Airbus, Alcan, Alcoa, British Energy, Rolls Royce, BNF and Jaguar. Major initiatives include the £6M EPSRC-Manchester Portfolio Partnership in Light Alloys for Environmentally Sustainable Transport and the Materials Performance Centre, a research alliance established with Nexia Solutions (supported by the NDA) in 2002, and partnered with British Energy, Serco Assurance, EDF and Westinghouse.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance. Read more
Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance.

Research Focus

The research extends from fundamental science, and the `blue skies' development of novel technologies and techniques, to the very applied, with the aim of improving our understanding of the basic governing principles, process simulation and physical modelling. While our research is broad ranging, we focus on light alloys for aerospace and transport applications, high-temperature materials for aeroengines and power generation, and metal composites, as well as the failure of metallic materials, their environmental degradation and surface treatment. The research is supported by state of the art equipment for materials characterisation, testing, simulation and processing.

Examples of recent student PhD projects include; Microstructure Modelling for Friction Stir Welding, Laser Surface treatment of Aerospace Alloys, Advanced Strain Mapping for Structural Integrity application, Dynamic Grain Growth in Super Plastic Forming, Dynamics and Morphology of Stress Corrosion Cracking Using 3D X-ray Tomography, and Laser Depositioning of Nickel Base Superalloys.

Industry links

We have strong links with industry and the funding councils and sponsorship from global companies, including; Airbus, Alcan, Alcoa, British Energy, Rolls Royce, BNF and Jaguar. Major initiatives include the £6M EPSRC-Manchester Portfolio Partnership in Light Alloys for Environmentally Sustainable Transport and the Materials Performance Centre, a research alliance established with Nexia Solutions (supported by the NDA) in 2002, and partnered with British Energy, Serco Assurance, EDF and Westinghouse.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Composite Materials research degrees are part of a forward-thinking area of research in the school. Read more
The Composite Materials research degrees are part of a forward-thinking area of research in the school. We have close links with the Northwest Regional Development Agency and other leading companies such as, Quickstep, a manufacturer of autoclave processing equipment, as well as a large number of suppliers in the aircraft industry.

Active research

Current research covers interfacial phenomena in composite materials, natural composites and rapid composites manufacture. The deformation mechanics of a range of high performance synthetic reinforcement fibres for composites are explored, as are those of natural and regenerated cellulose fibres. In the later case the main emphasis is on understanding the relationships between the microstructure and molecular structure of these materials and their mechanical properties. Molecular dynamics modelling together with experimental studies have been used to gain an improved insight into the behaviour of natural fibres.

Northwest Composites Centre

We are actively involved with the Northwest Composites Centre, a collaboration which incorporates researchers from several schools in the university, together with colleagues from the University of Liverpool, University of Bolton and Lancaster University covering a wide range of polymer and metallic composites. The hub of this activity is based here at the School of Materials, established through a £2.1m grant from NWDA, and has facilities for rapid processing of composites through a variety of new technologies, including microwave and radio frequency heating as well as Quickstep. There are also extensive facilities for the characterisation of composites.

There are a large number of researchers working in the centre, nearly all on the rapid processing of composites with a view to improving the cycle time and properties of composites. These involve not just the use of rapid curing techniques, but also textile structures for next generation 3 D composites. The evaluation of these materials is also an important part of the projects and therefore supported by state-of-the-art equipment.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Textile Science and Technology research degrees are part of a multi-disciplinary School of Materials. State-of-the-art facilities and a leading academic team, the largest and most comprehensive in Europe, are complemented by innovative research areas, and make this an exciting and forward-looking area for research. Read more
The Textile Science and Technology research degrees are part of a multi-disciplinary School of Materials. State-of-the-art facilities and a leading academic team, the largest and most comprehensive in Europe, are complemented by innovative research areas, and make this an exciting and forward-looking area for research.

Innovation

Textiles are a platform for innovation. Our research draws on the natural flexibility and versatility of fibres to produce novel fibre structures and physical properties. Through an integrated approach, our research expertise has been established across a broad technological base allowing multi-disciplinary problems to be solved.

High Performance Textiles

A huge manufacturing and commercial area in the textile science and technology sector is High Performance Technical Textiles. Such textiles require the specialist equipment infrastructure and critical scientific mass available at Manchester and in turn, allow us to carry out focused research and collaborate with important industry sectors, such as aerospace composites, where 3D textile structures are critical to lowering weight, maintaining strength and improving efficiency and economy.

International links

We work closely with various international research centres. Collaboration with the Faraday Technitex Centre, focusing on Technical Textiles, has assisted UK industry to develop novel performance materials and technology. We also have an important partnership in novel chemical processing with the Lenzig supported Christian Doppler Laboratory, which is primarily focused on the development of the sustainable cellulosic materials sector.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Textile Science and Technology research degrees are part of a multi-disciplinary School of Materials. State-of-the-art facilities and a leading academic team, the largest and most comprehensive in Europe, are complemented by innovative research areas, and make this an exciting and forward-looking area for research. Read more
The Textile Science and Technology research degrees are part of a multi-disciplinary School of Materials. State-of-the-art facilities and a leading academic team, the largest and most comprehensive in Europe, are complemented by innovative research areas, and make this an exciting and forward-looking area for research.

Innovation

Textiles are a platform for innovation. Our research draws on the natural flexibility and versatility of fibres to produce novel fibre structures and physical properties. Through an integrated approach, our research expertise has been established across a broad technological base allowing multi-disciplinary problems to be solved.

High Performance Textiles

A huge manufacturing and commercial area in the textile science and technology sector is High Performance Technical Textiles. Such textiles require the specialist equipment infrastructure and critical scientific mass available at Manchester and in turn, allow us to carry out focused research and collaborate with important industry sectors, such as aerospace composites, where 3D textile structures are critical to lowering weight, maintaining strength and improving efficiency and economy.

International links

We work closely with various international research centres. Collaboration with the Faraday Technitex Centre, focusing on Technical Textiles, has assisted UK industry to develop novel performance materials and technology. We also have an important partnership in novel chemical processing with the Lenzig supported Christian Doppler Laboratory, which is primarily focused on the development of the sustainable cellulosic materials sector.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Biomedical Materials research degrees cover an exciting area of research in the School focusing both on fundamental understanding of interactions between man-made materials and biological tissues and the development of useful applications. Read more
The Biomedical Materials research degrees cover an exciting area of research in the School focusing both on fundamental understanding of interactions between man-made materials and biological tissues and the development of useful applications. We have close links with the world's leading pharmaceutical and medical device companies and the clinical applications of our research impact many areas of medicine.

The subject

The subject of biomedical materials covers those materials that are used in the context of biology and medicine, usually to evaluate, treat, augment or replace any tissue, organ or function of the body. In surgery, a biomaterial may be a synthetic material used to replace part of a living system or to function in intimate contact with living tissue.

A new area in biomaterials involves the exploration of nanotechnology for drug delivery, biological sensing or tissue regeneration. Examples of these bionanomaterials are small particles that may be used for the delivery of drug molecules to target sites within the body or to detect diseased areas.

Biomaterials are produced using chemical, physical, mechanical processes and they often employ or mimic biological phenomena in order for them to interact with their biological surroundings in defined ways.

Application of research

The clinical applications of our research impact many areas of medicine, including drug delivery, cancer, wound healing, stem cell technology, repair and regeneration of nerve, tendon, cartilage, bone, intevertebral disc, skin, ligament and cornea.

Industry collaboration

We have strong ties with industry, including ongoing collaboration with Smith & Nephew, Johnson & Johnson, and Versamatrix A/S (Denmark), developing novel biomaterial based strategies for wound healing, bone repair, control of inflammation and drug delivery.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Paper Science research degrees are part of a dynamic research area within the school. We have close links with industry and much of our research impacts directly on current industry practice. Read more
The Paper Science research degrees are part of a dynamic research area within the school. We have close links with industry and much of our research impacts directly on current industry practice. Our academic team are highly rated within the paper science sector, and are regarded as experts in their field.

The subject

The range of materials classed as paper is diverse, from bathroom tissue to cardboard; but, despite the physical differences, they have the same chemical composition, consisting primarily of natural cellulosic fibres. The difference in the type of paper arises from the choice of raw material and the influence of the manufacturing process.

Our research

Our research covers the influence of factors, such as recycling and process chemistry, on the physical properties of the sheet, and looks at ways to improve them. We also look at improving the efficiency of raw materials and energy in manufacturing processes.

Industry links

We have strong ties with industry, including collaboration with Aylesford Newsprint, Billerud, Abitibi Consolidated, and M-Real. Our research impacts directly on paper manufacturers, and their suppliers and customers, and we are consistently approached by industry to collaborate and give expert advice on research projects.

Research projects

Some of our recent research projects include:
-Analysis of factors affecting the pore size distribution of paper
-Measurement and modelling of paper shrinkage during manufacture

The influence of sheet uniformity and starch on the strength of recycled board

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Nanostructured Materials research degrees are part of a large and multidisciplinary activity within the School of Materials. We have strong links with industry and leading research councils. Read more
The Nanostructured Materials research degrees are part of a large and multidisciplinary activity within the School of Materials. We have strong links with industry and leading research councils.

Fundamental research

The ability to characterise and manipulate the structure of matter on the nanoscale is fundamental to the development of advanced structural and functional materials. Our research, therefore, is broad-ranging and encompasses composites, fibres, surface-engineering and advanced characterisation techniques.

Industry links

We have strong links with industry worldwide and our work impacts directly on current practice within the sector. Industrial sponsors of our research include DeBeers, Gatan, British Vita, and research and trade organisations EPSRC, DTI and EC.

Research interests

Current research interests in this area include:
-Nanoporous substrates for tissue engineering
-Nanostructured surfaces for improved environmental resistance
-Nanoengineering using lasers
-Polymer nanocomposites

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Nanostructured Materials research degrees are part of a large and multidisciplinary activity within the School of Materials. We have strong links with industry and leading research councils. Read more
The Nanostructured Materials research degrees are part of a large and multidisciplinary activity within the School of Materials. We have strong links with industry and leading research councils.

Fundamental research

The ability to characterise and manipulate the structure of matter on the nanoscale is fundamental to the development of advanced structural and functional materials. Our research, therefore, is broad-ranging and encompasses composites, fibres, surface-engineering and advanced characterisation techniques.

Industry links

We have strong links with industry worldwide and our work impacts directly on current practice within the sector. Industrial sponsors of our research include DeBeers, Gatan, British Vita, and research and trade organisations EPSRC, DTI and EC.

Research interests

Current research interests in this area include:
-Nanoporous substrates for tissue engineering
-Nanostructured surfaces for improved environmental resistance
-Nanoengineering using lasers
-Polymer nanocomposites

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
Our Polymer Science and Engineering research programmes have a long and esteemed history and today span a diverse range of themes and topics that have relevance to industrial needs worldwide. Read more
Our Polymer Science and Engineering research programmes have a long and esteemed history and today span a diverse range of themes and topics that have relevance to industrial needs worldwide.

Focus for polymer research

Our polymer research is closely integrated and encompasses the research of several members of academic staff, both individually and in collaboration. The research is built around fundamental studies of structure-property relationships for polymer materials of current and future importance.

Active areas of polymer research include:
-Biopolymers
-Coatings and Films
-Composites
-Deformation Micromechanics
-Fibres
-Multiphase Polymers
-Polymer Colloids
-Polymerisation
-Polymer Processing
-Responsive Polymers

Industry impact

Many of our polymer research projects are carried out in collaboration with industry and have important implications for the polymer materials sector.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less
The Biomedical Materials research degrees cover an exciting area of research in the School focusing both on fundamental understanding of interactions between man-made materials and biological tissues and the development of useful applications. Read more
The Biomedical Materials research degrees cover an exciting area of research in the School focusing both on fundamental understanding of interactions between man-made materials and biological tissues and the development of useful applications. We have close links with the world's leading pharmaceutical and medical device companies and the clinical applications of our research impact many areas of medicine.

The subject

The subject of biomedical materials covers those materials that are used in the context of biology and medicine, usually to evaluate, treat, augment or replace any tissue, organ or function of the body. In surgery, a biomaterial may be a synthetic material used to replace part of a living system or to function in intimate contact with living tissue.

A new area in biomaterials involves the exploration of nanotechnology for drug delivery, biological sensing or tissue regeneration. Examples of these bionanomaterials are small particles that may be used for the delivery of drug molecules to target sites within the body or to detect diseased areas.

Biomaterials are produced using chemical, physical, mechanical processes and they often employ or mimic biological phenomena in order for them to interact with their biological surroundings in defined ways.

Application of research

The clinical applications of our research impact many areas of medicine, including drug delivery, cancer, wound healing, stem cell technology, repair and regeneration of nerve, tendon, cartilage, bone, intevertebral disc, skin, ligament and cornea.

Industry collaboration

We have strong ties with industry, including ongoing collaboration with Smith & Nephew, Johnson & Johnson, and Versamatrix A/S (Denmark), developing novel biomaterial based strategies for wound healing, bone repair, control of inflammation and drug delivery.

Read less
Our Polymer Science and Engineering research programmes have a long and esteemed history and today span a diverse range of themes and topics that have relevance to industrial needs worldwide. Read more
Our Polymer Science and Engineering research programmes have a long and esteemed history and today span a diverse range of themes and topics that have relevance to industrial needs worldwide.

Focus for polymer research

Our polymer research is closely integrated and encompasses the research of several members of academic staff, both individually and in collaboration. The research is built around fundamental studies of structure-property relationships for polymer materials of current and future importance.

Active areas of polymer research include:
-Biopolymers
-Coatings and Films
-Composites
-Deformation Micromechanics
-Fibres
-Multiphase Polymers
-Polymer Colloids
-Polymerisation
-Polymer Processing
-Responsive Polymers

Industry impact

Many of our polymer research projects are carried out in collaboration with industry and have important implications for the polymer materials sector.

Read less
The Ceramics and Glasses research degrees are part of a progressive research area within the school; we have close links with industry and research councils and we work collaboratively with them on many areas of research within the subject. Read more
The Ceramics and Glasses research degrees are part of a progressive research area within the school; we have close links with industry and research councils and we work collaboratively with them on many areas of research within the subject.

Industrial application

Our research is concerned with the processing, characterisation and applications of structural and functional ceramic materials. Structural ceramics are used in engineering applications due to a combination of high strength, chemical / thermal resistance and extreme hardness. In contrast, functional ceramics exhibit unique electrical, magnetic and optical properties, which lead to applications in a diverse range of electronic components - filters in mobile telecommunications, exhaust gas sensors and pyroelectric thermal imaging cameras.

We are engaged in research to understand the structure-property relationships in a wide range of ceramic materials and to develop materials / components with enhanced properties. Materials are developed by conventional powder processing methods and by novel processing procedures.

Research projects

Active projects in this area involve a wide range of processing techniques for functional and structural materials - these techniques are employed in industries as diverse as power generation, mobile telecommunications, aerospace and medical implants. To understand the microstructure-property relationships for the ceramics, we make extensive use of specialist characterisation facilities available in the school and in partner institutions nationally and internationally.

Industrial links

Through our close relationship with industry, we ensure that the research we carry out is relevant and focused on the requirements of new technology. We currently collaborate on research with, amongst others, Rolls-Royce, British Nuclear Fuel, Xaar Printing Technology, Powerwave, Morgan Electroceramics, and BAE Systems. We are also supported by EPSRC, the European Commission, and British Energy.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

Read less

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