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Masters Degrees (Materials Science And Engineering)

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Materials Science and Engineering offers interdisciplinary programs leading to the degrees of master of science and doctor of philosophy. Read more
Materials Science and Engineering offers interdisciplinary programs leading to the degrees of master of science and doctor of philosophy. Established in 2002, the program offers both the MS and PhD degree in materials science and engineering. While the program is relatively young, the participating departments and faculty on campus have an extensive legacy of research and of offering relevant materials science and engineering academic training.

From the smallest of the small to the opposite end of the spectrum, our students develop a foundation in the principles of materials science, selecting an atomic/nano approach or a bulk/macro approach. This foundation is then coupled with specialized knowledge in one area of materials, such as: energy production, storage and transmission; nanomaterials for a range of applications; electronic materials with a specialization in flexible electronics; biomaterials; modeling and mechanical behavior.

Recent doctoral graduate placements include: Post Doctoral Fellowship at Massachusetts Institute of Technology, Reliability Engineer for Microsoft Corporation, Research Scientist for Toyota, Senior Research Engineer at LG Electronics, Post Doctoral Fellowship at Northwest National Lab, Senior Process Engineer at Global Foundries

Graduate Degrees Offered

- MS with an engineering emphasis or a science emphasis

All applicants must also submit the following:

- Online graduate degree application and application fee
- Transcripts from each college/university which you attended
- Three letters of recommendation
- Personal statement (2-3 pages) describing your reasons for pursuing graduate study, your career aspirations, your special interests within your field, and any unusual features of your background that might need explanation or be of interest to your program's admissions committee.
- Resume or Curriculum Vitae (max. 2 pages)
- Official GRE scores

And, for international applicants:
- International Student Financial Statement form
- Official bank statement/proof of support
- Official TOEFL, IELTS, or PTE Academic scores

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The master of science degree in materials science and engineering, offered jointly by the College of Science and the Kate Gleason College of Engineering, is designed with a variety of options to satisfy individual and industry needs in the rapidly growing field of materials. Read more
The master of science degree in materials science and engineering, offered jointly by the College of Science and the Kate Gleason College of Engineering, is designed with a variety of options to satisfy individual and industry needs in the rapidly growing field of materials.

The objectives of the program are threefold:

- With the advent of new classes of materials and instruments, the traditional practice of empiricism in the search for and selection of materials is rapidly becoming obsolete. Therefore, the program offers a serious interdisciplinary learning experience in materials studies, crossing over the traditional boundaries of such classical disciplines as chemistry, physics, and electrical, mechanical, and microelectronic engineering.

- The program provides extensive experimental courses in diverse areas of materials-related studies.

- The program explores avenues for introducing greater harmony between industrial expansion and academic training.

Plan of study

A minimum of 30 semester credit hours is required for the completion of the program. This includes five required core courses, graduate electives, and either a thesis or project. The core courses are specially designed to establish a common base of materials-oriented knowledge for students with baccalaureate degrees in chemistry, chemical engineering, electrical engineering, mechanical engineering, physics, and related disciplines, providing a new intellectual identity to those involved in the study of materials.

The program has an emphasis on experimental techniques, with one required experimental course as part of the core. Additional experimental courses are available for students who wish to pursue course work in this area. These courses are organized into appropriate units covering many aspects of the analysis of materials. This aspect of the program enhances a student’s confidence when dealing with materials-related problems.

- Electives

Elective courses may be selected from advanced courses offered by the School of Chemistry and Materials Science or, upon approval, from courses offered by other RIT graduate programs. Elective courses are scheduled on a periodic basis. Transfer credit may be awarded based on academic background beyond the bachelor’s degree or by examination, based on experience.

- Thesis/Project

Students may choose to complete a thesis or a project as the conclusion to their program. Students who pursue the thesis option take two graduate electives, complete nine semester credit hours of research, and produce a thesis paper. The project option includes four graduate electives and a 3 credit hour project.

Admission requirements

To be considered for admission to the MS program in materials science and engineering, candidates must fulfill the following requirements:

- Hold a baccalaureate degree in chemistry, physics, chemical engineering, electrical engineering, mechanical engineering, or a related field from an accredited college or university,

- Submit official transcripts (in English) from all previously completed undergraduate and graduate course work,

- Submit two letters of recommendation, and

- Complete a graduate application.

- International applicants whose native language is not English must submit scores from the Test of English as a Foreign Language (TOEFL) and the Test of Written English (TWE). A minimum TOEFL score of 575 (paper-based) or 88-89 (Internet-based) is required. A 4.0 is required on the TWE. International English Language Testing System (IELTS) scores are accepted in place of the TOEFL exam. Minimum scores will vary; however, the absolute minimum score required for unconditional acceptance is 6.5. For additional information about the IELTS, please visit http://www.ielts.org. In addition, upon arrival at RIT, international students are required to take the English language exams, administered by the English Language Center. Individuals scoring below an established minimum will be referred to the center for further evaluation and assistance. These students are required to follow the center’s recommendations regarding language course work. It is important to note that this additional course work may require additional time and financial resources to complete the degree requirements. Successful completion of this course work is a requirement for the program.

Candidates not meeting the general requirements may petition for admission to the program. In such cases, it may be suggested that the necessary background courses be taken at the undergraduate level. However, undergraduate credits that make up deficiencies may not be counted toward the master’s degree.

Any student who wishes to study at the graduate level must first be admitted to the program. However, an applicant may be permitted to take graduate courses as a nonmatriculated student if they meet the general requirements mentioned above.

Additional information

- Part-time study

The program offers courses in the late afternoon and evenings to encourage practicing scientists and engineers to pursue the degree program without interrupting their employment. (This may not apply to courses offered off campus at selected industrial sites.) Students employed full time are normally limited to a maximum of two courses, or 6 semester credit hours, each semester. A student who wishes to register for more than 6 semester credit hours must obtain the permission of his or her adviser.

- Maximum limit on time

University policy requires that graduate programs be completed within seven years of the student's initial registration for courses in the program. Bridge courses are excluded.

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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.

Coursework and assessment

The taught part of the programme is based on discrete compulsory and optional taught course units.

Course unit details

Example of taught units on this course are:

  • Introduction to Materials Science
  • Advanced Research Methods
  • Principles of Polymers and Polymer Composites
  • Control and Design of Polymerisation Reactions
  • Polymer Physics and Physical Properties
  • Advanced Composites
  • Soft Matter

Disability support

Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: 

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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It is estimated 70 per cent of innovations are due to an advance in materials. This course provides a solid grounding in all types of man-made materials, and aims to prepare you for a career in industry by teaching you the concepts and theories that make materials science and engineering possible. Read more

About the course

It is estimated 70 per cent of innovations are due to an advance in materials. This course provides a solid grounding in all types of man-made materials, and aims to prepare you for a career in industry by teaching you the concepts and theories that make materials science and engineering possible.

Our research-led teaching introduces you to all the latest developments, and you’ll have the option to specialise in the area that interests you the most.

A welcoming department

A friendly, forward-thinking community, our students and staff are on hand to welcome you to the department and ensure you settle into student life.

Your project supervisor will support you throughout your course. Plus you’ll have access to our extensive network of alumni, offering industry insight and valuable career advice to support your own career pathway.

Your career

Prospective employers recognise the value of our courses, and know that our students can apply their knowledge to industry. Our graduates work for organisations including Airbus, Rolls-Royce, the National Nuclear Laboratory and Saint-Gobain. Roles include materials development engineer, reactor engineer and research manager. They also work in academia in the UK and abroad.

90 per cent of our graduates are employed or in further study 6 months after graduating, with an average starting salary of £27,000, the highest being £50,000.

Equipment and facilities

We have invested in extensive, world-class equipment and facilities to provide a stimulating learning environment. Our laboratories are equipped to a high standard, with specialist facilities for each area of research.

Materials processing

Tools and production facilities for materials processing, fabrication and testing, including wet chemical processing for ceramics and polymers, rapid solidification and water atomisation for nanoscale metallic materials, and extensive facilities for deposition of functional and structural coatings.

Radioactive nuclear waste and disposal

Our £3million advanced nuclear materials research facility provides a high-quality environment for research on radioactive waste and disposal. Our unique thermomechanical compression and arbitrary strain path equipment is used for simulation of hot deformation.

Characterisation

You’ll have access to newly refurbished array of microscopy and analysis equipment, x-ray facilities, and surface analysis techniques covering state-of-the-art XPS and SIMS. There are also laboratories for cell and tissue culture, and facilities for measuring electrical, magnetic and mechanical properties.

The Kroto Research Institute and the Nanoscience and Technology Centre enhance our capabilities in materials fabrication and characterisation, and we have a computer cluster for modelling from the atomistic through nano and mesoscopic to the macroscopic.

Stimulating learning environment

An interdisciplinary research-led department; our network of world leading academics at the cutting edge of their research inform our courses providing a stimulating, dynamic environment in which to study.

Teaching and assessment

Working alongside students and staff from across the globe, you’ll tackle real-world projects, and attend lectures, seminars and laboratory classes delivered by academic and industry experts.

You’ll be assessed by formal examinations, coursework assignments and a dissertation.

Core modules

Science of Materials; Materials Processing and Characterisation; Materials Selection, Properties and Applications; Technical Skills Development; Heat and Materials; Research project in an area of your choice.

Examples of optional modules

Functional and Structural Ceramics; Design and Manufacture of Composites; Materials 
for Energy Applications; Metals Processing Case Studies; Glasses and Cements; Metallurgical Processing; Nanostructures 
and Nanostructuring.

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If you’re a graduate from a science, mathematics, technology or another engineering discipline, this programme provides the knowledge and skills to convert… Read more

If you’re a graduate from a science, mathematics, technology or another engineering discipline, this programme provides the knowledge and skills to convert to a specialism in materials science and engineering or metallurgy to meet the present needs and future challenges of advanced materials and manufacturing in areas such as transportation, bioengineering, energy, electronics and information technology, sport and sustainable development.

Alternatively, if you’re already a professional engineer in the materials sector, you’ll have the chance to expand your expertise to enhance your career prospects.

Core modules cover key topics such as materials structures, processing-structure-property relationships, characterisation and failure analysis. You’ll also choose one from three groups of optional modules to focus your specialism to suit your own career plans and interests. Taught by experts in world-class facilities, you’ll gain the skills to thrive in a growing and fast-changing field.



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Materials underpin almost all industrial sectors and the global challenges have increased the demand for new materials. Accordingly, there is a growing demand for materials engineers and researchers worldwide and in rapidly developing countries in particular. Read more
Materials underpin almost all industrial sectors and the global challenges have increased the demand for new materials. Accordingly, there is a growing demand for materials engineers and researchers worldwide and in rapidly developing countries in particular. The School of Metallurgy and Materials has long been a centre of excellence in materials research and education.

This one-year master course comprises 12 taught modules (two-thirds of the year) taken in Semesters I and II and an individual research project (one-third of the year) carried out in Semester III & summer. In addition to technical modules, the course also provides training for transferable skills such as the Team Skills Development module undertaken in a residential environment to facilitate the development of the team ethos and interpersonal skills.

Research projects can be carried out in a broad range of topics related to Materials Science and Engineering in any of the Research Groups within the School of Metallurgy and Materials or in industry. The project involves full-time research for one third of the academic year. The project report (which should be a maximum of 8,000 words in length) will be internally assessed by two academic staff.

About the School of Metallurgy & Materials Engineering

The School of Metallurgy and Materials ranked in the top quartile in the UK for world-leading research in the Research Excellence Framework (REF). Overall 86% of the research in the School was recognised as internationally excellent of which 31% was given the higher accolade of being world-leading.
We are considered to be the leading school for many areas of metallurgical research. Our numerous interactions with industry span agreements lasting between three months and twelve years.
We are proud to encompass a wide range of interests in the processing, characterisation, assessment and modelling of materials, including:
- Alloy Processing
- Characterisation and Modelling
- Engineering Properties of Materials
- Functional Materials Processing

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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Advances in technology depends more and more on the discovery and development of new materials having particular desired properties. Read more
Advances in technology depends more and more on the discovery and development of new materials having particular desired properties. In addition to mechanical strength, various structural, optical, electrical, magnetic and thermal properties are demanded from materials depending on the application. The field of Materials Science and Engineering investigates different classes of materials -metals, ceramics, polymers, electronic materials, biomaterials- with an emphasis on the relationships between the underlying structure and the processing, properties, and performance of the materials.
Understanding various material properties is the first step in finding ways to tailor these properties to meet some particular need or application, and for creating entirely new materials having particular desired properties. The M.S. program in Material Science & Engineering at Koç University is an interdisciplinary program with the objective of giving the students the fundamental physical and chemical knowledge required for material synthesis, structure-property characterization and processing; and complementing this with practical laboratory experience.

Current faculty projects and research interests:

• Nanostructured materials
• Photonics & laser materials
• Polymeric materials & composites
• Fuel cells & hydrogen storage materials
• Processing & device applications
• Protein biochemistry & biotechnology
• Micro-optics & micro-nano system Technologies

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This Master of Science programme is taught entirely in English to stimulate the student in acquiring greater familiarity with the terminology used internationally. Read more

Mission and Goals

This Master of Science programme is taught entirely in English to stimulate the student in acquiring greater familiarity with the terminology used internationally. The objective of the programme is to prepare a professional figure expert in materials and in the design of processes and manufactured goods. Within the scope of the study plan a number of specific specialisations are foreseen:
- Surface Engineering
- Polymer Engineering
- Nanomaterials and Nanotechnology
- Engineering Applications
- Micromechanical Engineering

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/materials-engineering-and-nanotechnology/

Career Opportunities

The Master of Science graduate in Materials and Nanotechnology Engineering has the ability to devise and manage innovation in the materials industry; he/she finds employment mainly in companies specialised in producing, processing and design various materials and components, as well as in the area of the development of new applications in the mechanical, chemical, electronics, energy, telecommunications, construction, transport, biomedical, environmental and restoration industries as well as in research and development centres of companies and public bodies.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Materials_Engineering_and_Nanotechnology_04.pdf
The Master of science programme aims at preparing specialists with strong technical skills for innovation of processes and applications of new materials and nanotechnologies. One of the major focuses of the MSc is on sustainable technologies and nanotechnologies for advanced applications. The city of Milan and its surroundings are fertile ground for social and technical culture, with a variety of small enterprises open to innovation and new technologies and working in niche fields, where non-traditional materials are key to future developments. The job market welcomes Material Engineers as professionals capable of handling complex problems directly related to the production, treatment and applications of materials, acknowledging the high level of education obtained at the Politecnico di Milano through original methodologies and new technologies.
The programme is taught in English.

Subjects

- Mathematical methods for materials engineering
- Advanced materials chemistry
- Polymer science and engineering
- Principles of polymer chemistry + Fundamentals of polymer mechanics
- Solid state physics
- Mechanical behavior of materials
- Cementitous and ceramic materials engineering
- Advanced Materials
- Functional materials + nanostructured materials
- Durability of materials
- Failure and control of Materials
- Surface engineering
- Thesis work

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/materials-engineering-and-nanotechnology/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/materials-engineering-and-nanotechnology/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

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The University of Bath Civil Engineering. Innovative Structural Materials MSc is a full-time, one-year taught postgraduate course. Read more

The University of Bath Civil Engineering: Innovative Structural Materials MSc is a full-time, one-year taught postgraduate course.

Students study a range of modules before carrying out an individual research dissertation project in order to complete their Master of Science degree.

The course produces graduates with an in-depth and practical understanding of the use of innovative structural engineering materials in the provision of sustainable and holistic construction solutions for the built environment.

The use of construction materials is key to infrastructural development globally. New approaches are now needed for innovative renewable and low carbon structural engineering materials.

This MSc course will not only help prepare you for an exciting career in the industry, but it will also help prepare you to continue your studies onto a Doctor of Philosophy research programme.

Visit the website http://www.bath.ac.uk/engineering/graduate-school/taught-programmes/structural-engineering/

Learning outcomes

The course is aimed at engineering and science graduates who wish to work in the construction industry.

As a student you will be provided with the practical knowledge and tools to support you in the use of innovative structural engineering materials in the context of sustainable and holistic construction. You will also learn how to harness that knowledge in a business environment. You will gain analytical and team working skills to enable you to deal with the open-ended problems typical of structural engineering practice.

The MSc is based on research expertise of the BRE Centre for Innovative Construction Materials (http://www.bath.ac.uk/ace/research/cicm/) and is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired a partial CEng accredited undergraduate first degree. Please visit the Joint Board of Moderators (http://www.jbm.org.uk/) for further information about accreditation.

Collaborative working

The course includes traditionally taught subject-specific units and business and group-orientated modular work. These offer you the chance to gain experience in design, project management and creativity, while working with students from other subjects.

Project Work

Group project work:

In semester 2 you undertake a cross-disciplinary group activity for your professional development, simulating a typical industrial work situation.

Individual project work:

In the final semester, you undertake an individual research project directly related to key current research at the University, often commissioned by industry.

Structure in detail

A full list of units can be found on the programme catalogue (http://www.bath.ac.uk/catalogues/2015-2016/ar/ar-proglist-pg.html#AC).

Semester 1 (October-January)

The first semester provides a foundation in the most significant issues relating to the sustainable use of innovative structural engineering materials in design and construction; and involves units in natural building materials, advanced timber engineering, advanced composites, sustainable concrete technology and architectural structures.

- Five taught compulsory units

- Includes coursework involving laboratory or small project sessions.

- Typically each unit consists of 22 hours of lectures and 11 hours of tutorials, and may additionally involve a number of hours of laboratory activity and field trips with approximately 65-70 hours of private study (report writing, laboratory results processing and revision for examinations).

Semester 2 (February-May)

Semester 2 consists of a further 30 credits comprising of five core 6 credit units. These units include:

- Materials engineering in construction

- Advanced timber engineering

- Engineering project management.

Students will undertake a group-based design activity and an individual project scoping and planning unit (Project Unit 1). The group-based activity involves application of project management techniques and provides the basis for an integrated approach to Engineering, but with the possibility of specialising in the chosen master's topic.

It is a feature of this programme that the project work proceeds as far as possible in a way typical of best industrial practice. The Semester 2 project activities have significant planning elements including the definition of milestones and deliverables according to a time-scale, defined by the student in consultation with his/her academic supervisor and (where appropriate) his/her industrial advisor.

Summer/Dissertation Period (June-September)

Individual project leading to MSc dissertation.

Depending on the chosen area of interest, the individual project may involve theoretical and/or experimental activities; for both such activities students can use the department computer suites and well-equipped and newly refurbished laboratories for experimental work. The individual projects are generally carried out under the supervision of a member of academic staff.

There may be an opportunity for some projects to be carried out with the Building Research Establishment (BRE).

Subjects covered

- Advanced structures

- Advanced composites in construction

- Advanced timber engineering

- Materials engineering in construction

- Natural building materials

- Sustainable concrete technology

About the department

The Department of Architecture and Civil Engineering brings together the related disciplines of Architecture and Civil Engineering. It has an interdisciplinary approach to research, encompassing the fields of Architectural History and Theory, Architectural and Structural Conservation, Lightweight Structures, Hydraulics and Earthquake Engineering and Dynamics.

Our Department was ranked equal first in the Research Excellence Framework 2014 for its research submission in the Architecture, Built Environment and Planning unit of assessment.

Half of our research achieved the top 4* rating, the highest percentage awarded to any submission; and an impressive 90% of our research was rated as either 4* or 3* (world leading/ internationally excellent in terms of originality, significance and rigour).

The dominant philosophy in the joint Department is to develop postgraduate programmes and engage in research where integration between the disciplines is likely to be most valuable. Research is carried out in collaboration with other departments in the University, particularly Management, Computer Science, Mechanical Engineering, and Psychology.

Find out how to apply here - http://www.bath.ac.uk/study/pg/apply/

Funding

The following postgraduate funding may be available to study the Civil Engineering: Innovative Structural Materials MSc at The University of Bath.

UK postgraduate loans:

Erasmus funding:

Funding from FindAMasters:

Fees

UK / EU: £9.500

International: £20,300



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The programme is co-organised by Vrije Universiteit Brussel (VUB) and Universite Libre de Bruxelles (ULB), offering students the possibility to obtain a double master's degree at the end of the programme. Read more

About the programme

The programme is co-organised by Vrije Universiteit Brussel (VUB) and Universite Libre de Bruxelles (ULB), offering students the possibility to obtain a double master's degree at the end of the programme. The first year of courses is taught at the ULB Engineering Campus in Brussels, while the second year is taught at VUB.

The Master of Chemical and Materials Engineering educates students to become innovative engineers who will contribute to their profession and to society. Engineers in chemistry and materials play a unique role in sustainable development, where they must manage resources, energy and the environment in order to develop and produce novel materials and chemical commodities. Our graduates are prepared to face the demands of the modern technological employment field and for an international career with English as their professional language.

Course content

The Master in Chemical and Material Engineering (120 ECTS) offers a solid core of courses in both of these engineering fields. The integrated and the multidisciplinary approach provides students up-to-date knowledge enabling them to propose innovative engineering solutions in numerous modern technological sectors. Students have the possibility to specialize in Process technology or Material Science.

The Master of Chemical and Materials Engineering program consists of two profiles: Process Technology and Materials.

Profile: Process Technology:
The Process Technology orientation trains students to become engineers who are employable and innovative both in production units (operation and optimization of production facilities) and in engineering groups (develop new production units that meet desired performance specifications). An emphasis is placed on the biotechnology and food industries. Students are also trained to identify, solve and avoid environmental problems including waste management, water, air and soil pollution.

Profile: Materials:
The Materials orientation prepares students for the materials and materials technology sectors (metals, polymers, ceramics and composites). Students are trained to become creative engineers capable of designing sustainable multi-functional materials which meet specific applications. Students also have the capacity to contribute to the whole life-cycle of materials from their processing into semi or full end products using environmentally friendly and safe production processes to their recycling.

Become a skilled scientific engineer

This Master offers:
- a unique interdisciplinary programme which prepares you for employment in a professional field related to chemical engineering, materials or environmental technology.
- a high level scientific education that prepares you to a wide range of job profiles.
- the possibility to work in close contact with professors who are internationally recognized in their own disciplines and favor interactive learning.

Curriculum

http://www.vub.ac.be/en/study/chemical-and-materials-engineering/programme

The programme is built up modularly:
1) the Common Core Chemical and Materials Engineering (56 ECTS)
2) the Specific Profile Courses (30 ECTS)
3) the master thesis (24 ECTS)
4) electives (10 ECTS) from 1 out of 3 options.
Each of the modules should be succesfully completed to obtain the master degree. The student must respect the specified registration requirements. The educational board strongly suggests the student to follow the standard learning track. Only this model track can guarantee a timeschedule without overlaps of the compulsory course units.

Common Core Chemical and Materials Engineering:
The Common Core Chemical and Materials Engineering (56 ECTS) is spread over 2 years: 46 ECTS in the first and 10 ECTS in the second year. The Common Core emphasizes the interaction between process- and materials technology by a chemical (molecular) approach. The Common Core consists out of courses related to chemistry, process technology and materials and is the basis for the Process Technology and the Materials profiles.

Specific Courses Profile Materials:
The profile 'Materials' (30 ECTS) consists out of 2 parts, spread over the 1st and the 2nd year of the model learning track: Materials I - 14 ECTS in MA1 and Materials II - 16 ECTS in MA2. The profile adds material-technological courses to the common core.

Specific Courses Profile Process Technology:
The profile 'Process Technology' (30 ECTS) consists out of 2 parts, spread over the 1st and the 2nd year of the model learning track: Process Technology I - 14 ECTS in MA1 and Process Technology II - 16 ECTS in MA2. The profile adds process technological courses to the common core.

Elective Courses:
The elective courses are divided into 3 options:
- Option 1: Internship (10 ECTS)
- Option 2: Elective courses (incl. internship of 6 ECTS)
- Option 3: Entrepreneurship
The student has to select one option and at least 10 ECTS within that option. All options belong to the 2nd year of the model learning track.

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This challenging inter-disciplinary programme spans the major classes of engineering materials used in modern high technology manufacturing and industry. Read more

This challenging inter-disciplinary programme spans the major classes of engineering materials used in modern high technology manufacturing and industry. The course has considerable variety and offers career opportunities across a wide range of industry sectors, where qualified materials scientists and engineers are highly sought after.

This course is accredited by the Institute of Materials, Minerals and Mining (IOM3), allowing progression towards professional chartered status (CEng) after a period of relevant graduate-level employment.

Core study areas include advanced characterisation techniques, surface engineering, processing and properties of ceramics and metals, design with engineering materials, sustainability and a project.

Optional study areas include plastics processing technology, industrial case studies, materials modelling, adhesive bonding, rubber compounding and processing, and polymer properties.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/materials/materials-science-tech/

Programme modules

Full-time Modules:

Core Modules

- Advanced Characterisation Techniques (SL)

- Surface Engineering (SL)

- Ceramics: Processing and Properties (SL)

- Design with Engineering Materials (SL)

- Sustainable Use of Materials (OW)

- Metals: Processing and Properties (SL)

- MSc Project

Optional Modules

- Plastics Processing Technology (OW)

- Industrial Case Studies (OW)

- Materials Modelling (SL)

Part-time Modules:

Core Modules

- Ceramics: Processing and Properties (DL)

- Design with Engineering Materials (DL)

- Sustainable Use of Materials (OW or DL)

- Metals: Processing and Properties (DL)

- Surface Engineering (DL)

- Plastics Processing Technology (OW)

- MSc Project

Optional Modules

- Industrial Case Studies (OW)

- Adhesive Bonding (OW)

- Rubber Compounding and Processing (OW or DL)

Alternative modules:*

- Polymer Properties (DL)

- Advanced Characterisation Techniques (SL)

- Materials Modelling (SL)

Key: SL = Semester-long, OW = One week, DL = Distance-learning

Alternative modules* are only available under certain circumstances by agreement with the Programme Director.

Selection

Interviews may be held on consideration of a prospective student’s application form. Overseas students are often accepted on their grades and strong recommendation from suitable referees.

Course structure, assessment and accreditation

The MSc comprises a combination of semester-long and one week modules for full-time students, whilst part-time students study a mix of one week and distance-learning modules.

MSc students undertake a major project many of which are sponsored by our industrial partners. Part-time student projects are often specified in conjunction with their sponsoring company and undertaken at their place of work.

All modules are 15 credits. The MSc project is 60 credits.

MSc: 180 credits – six core and two optional modules, plus the MSc project.

PG Diploma: 120 credits – six core and two optional modules.

PG Certificate: 60 credits – four core modules.

- Assessment

Modules are assessed by a combination of written examination, set coursework exercises and laboratory reports. The project is assessed by a dissertation, literature review and oral presentation.

- Accreditation

Both MSc programmes are accredited by the Institute of Materials, Minerals and Mining (IOM3), allowing progression towards professional chartered status (CEng) after a period of relevant graduate-level employment.

Careers and further Study

Typical careers span many industrial sectors, including aerospace, power generation, automotive, construction and transport. Possible roles include technical and project management, R&D, technical support to manufacturing as well as sales and marketing.

Many of our best masters students continue their studies with us, joining our thriving community of PhD students engaged in materials projects of real-world significance

Bursaries and Scholarships

Bursaries are available for both UK / EU and international students, and scholarships are available for good overseas applicants.

Why Choose Materials at Loughborough?

The Department has contributed to the advancement and application of knowledge for well over 40 years. With 21 academics and a large support team, we have about 85 full and part-time MSc students, 70 PhD students and 20 research associates.

Our philosophy is based on the engineering application and use of materials which, when processed, are altered in structure and properties.

Our approach includes materials selection and design considerations as well as business and environmental implications.

- Facilities

We are also home to the Loughborough Materials Characterisation Centre – its state of-the-art equipment makes it one of the best suites of its kind in Europe used by academia and our industrial partners.

The Centre supports our research and teaching activities developing understanding of the interactions of structure and properties with processing and product performance.

- Research

Our research activity is organised into 4 main research groups; energy materials, advanced ceramics, surface engineering and advanced polymers. These cover a broad span of research areas working on today’s global challenges, including sustainability, nanomaterials, composites and processing. However, we adopt an interdisciplinary approach to our research and frequently interact with other departments and Research Schools.

- Career prospects

Over **% of our graduates were in employment and / or further study six months after graduating. Our unrivalled links with industry are hugely beneficial to our students. We also tailor our courses according to industrial feedback and needs, ensuring our graduates are well prepared

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/materials/materials-science-tech/



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The MASt in Materials Science aims to train to Masters level students who already have a bachelors' degree in Materials Science. It is a predominantly taught course in which candidates work alongside the 4th-year students taking the integrated Cambridge BA/MSci Materials Science course. Read more

Overview

The MASt in Materials Science aims to train to Masters level students who already have a bachelors' degree in Materials Science. It is a predominantly taught course in which candidates work alongside the 4th-year students taking the integrated Cambridge BA/MSci Materials Science course. It is designed for students who may wish to pursue a professional career in Materials Science / Materials Engineering or related areas (in academic or industrial research) and who are already familiar with the subject.

The course allows students to continue a broad Materials Science education across a range of topics : the taught element consists of a series of approximately 16 modular lecture courses, covering a broad range of aspects of Materials Science, including Structural Materials, Device Materials, Materials Characterisation, Materials Chemistry and Biological & Pharmaceutical Materials. A research project is undertaken over 6 months, between October and March.

Specific aims are:
1. to build on the knowledge and ideas gained in prior Materials Science courses;
2. to develop a more specialised and in-depth understanding of Materials Science in selected areas;
3. to further develop analytical and presentational skills, both orally and in writing;
4. to provide training in investigating research problems, including gaining an understanding of relevant research techniques and also of the design and interpretation of experiments.

See the website http://www.graduate.study.cam.ac.uk/courses/directory/pcmmasmsc

Learning Outcomes

At the end of the course students should:
1. be able to apply the ideas and concepts introduced in the course to solve problems, do calculations, make predictions and critically evaluate information and ideas;
2. be able to demonstrate an understanding of the courses attended, and of their individual research projects;
3. be able to demonstrate practical, organisational and presentational skills that will enable them to continue successfully with research or in other professional careers;
4. be able to demonstrate the necessary skills and understanding required for a career in Materials Science.

Continuing

Students wishing to continue to PhD studies will usually be required to obtain at least a 'Commendable' result in the MASt.

Teaching

There are approximately 16 lecture modules focusing on advanced topics across a broad range of aspects of Materials Science, including Structural Materials, Device Materials, Materials Characterisation, Materials Chemistry and Biological & Pharmaceutical Materials. Details of the modules available this year can be found at: http://www.msm.cam.ac.uk/teaching/partIII.php.

Students may choose which lecture modules they wish to attend, and must prepare a minimum of 10 courses for examination.

Students also undertake a substantial individual research project, chosen from a set of topics proposed by academic staff. Work on this project accounts for about a third of the final credit.

- Feedback
The MASt is treated as an undergraduate course for the purposes of supervisions, such that on average students should expect to have at least one supervision per week during term, with written and verbal feedback on their work within 24 hours.

Online written reports are provided at the end of each term.

Students should expect to meet daily to weekly with their project demonstrator and weekly to termly with their project supervisor.

Students receive written feedback on all aspects of work submitted for summative assessment (reports, oral presentations, poster), within two weeks of the work being submitted.

Funding Opportunities

There are no specific funding opportunities advertised for this course. For information on more general funding opportunities, please follow the link below.

General Funding Opportunities http://www.graduate.study.cam.ac.uk/finance/funding

Find out how to apply here http://www.graduate.study.cam.ac.uk/courses/directory/pcmmasmsc/apply

See the website http://www.graduate.study.cam.ac.uk/courses/directory/pcmmasmsc

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The MASt in Materials Science aims to train to Masters level students who already have a bachelors' degree in Materials Science. It is a predominantly taught course in which candidates work alongside the 4th-year students taking the integrated Cambridge BA/MSci Materials Science course. Read more
The MASt in Materials Science aims to train to Masters level students who already have a bachelors' degree in Materials Science. It is a predominantly taught course in which candidates work alongside the 4th-year students taking the integrated Cambridge BA/MSci Materials Science course. It is designed for students who may wish to pursue a professional career in Materials Science / Materials Engineering or related areas (in academic or industrial research) and who are already familiar with the subject.

The course allows students to continue a broad Materials Science education across a range of topics : the taught element consists of a series of approximately 16 modular lecture courses, covering a broad range of aspects of Materials Science, including Structural Materials, Device Materials, Materials Characterisation, Materials Chemistry and Biological & Pharmaceutical Materials. A research project is undertaken over 6 months, between October and March.

Visit the website: http://www.graduate.study.cam.ac.uk/courses/directory/pcmmasmsc

Course detail

Specific aims are:

- to build on the knowledge and ideas gained in prior Materials Science courses;
- to develop a more specialised and in-depth understanding of Materials Science in selected areas;
- to further develop analytical and presentational skills, both orally and in writing;
- to provide training in investigating research problems, including gaining an understanding of relevant research techniques and also of the design and interpretation of experiments.

Learning Outcomes

At the end of the course students should:

- be able to apply the ideas and concepts introduced in the course to solve problems, do calculations, make predictions and critically evaluate information and ideas;
- be able to demonstrate an understanding of the courses attended, and of their individual research projects;
- be able to demonstrate practical, organisational and presentational skills that will enable them to continue successfully with research or in other professional careers;
- be able to demonstrate the necessary skills and understanding required for a career in Materials Science.

Format

There are approximately 16 lecture modules focusing on advanced topics across a broad range of aspects of Materials Science, including Structural Materials, Device Materials, Materials Characterisation, Materials Chemistry and Biological & Pharmaceutical Materials. Details of the modules available this year can be found at: http://www.msm.cam.ac.uk/teaching/partIII.php.

Students may choose which lecture modules they wish to attend, and must prepare a minimum of 10 courses for examination.

Students also undertake a substantial individual research project, chosen from a set of topics proposed by academic staff. Work on this project accounts for about a third of the final credit.

Assessment

- A final report of up to 7000 words, worth 12% of the total credit.
- An interim report worth 4% of the total credit.
- A project viva worth 4% of the total credit.
- A project poster worth 4% of the total credit.
- A project oral presentation worth 4% of the total credit.
- Termly progress assessments from project supervisor worth 2% of the total credit.
- Vacation project written report worth 1% of the total credit.
- Three 3-hr written examination papers worth a total of 68% of the credit.
An oral presentation of a vacation project worth 1% of the total credit.

Continuing

Students wishing to continue to PhD studies will usually be required to obtain at least a 'Commendable' result in the MASt.

How to apply: http://www.graduate.study.cam.ac.uk/applying

Funding Opportunities

There are no specific funding opportunities advertised for this course. For information on more general funding opportunities, please follow the link below.

General Funding Opportunities: http://www.2016.graduate.study.cam.ac.uk/finance/funding

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A Masters course providing the foundation for 21st century technologies - from fuel cells to aeroengines. Read more

A Masters course providing the foundation for 21st century technologies - from fuel cells to aeroengines

The complete masters (MSc) course in Advanced Engineering Materials provides you with an in-depth understanding of the key factors that govern the design and selection of materials for use in advanced engineering applications, as well as their processing, properties and stability.

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
  • Advanced Research Methods
  • Principles of Advanced Engineering Materials
  • Superalloys and High Performance Materials
  • Advanced Metals Processing
  • Advanced Composites
  • Graphene and Nanomaterials

Overseas students will require and ATAS certificate for this course. The ATAS certificate will expire after 6 months so please wait until May before applying. For a full list of the course units, please contact  . The JACS code for this course is J511 or J5.

Scholarships and bursaries

Unfortunately, The University of Manchester does not have any funding opportunities at present. There may be external funding opportunities, please see the link for more information:http://www.manchester.ac.uk/study/masters/funding/

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.

Disability support

Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: 

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. For more information, visit http://www.iom3.org  



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This MSc will suit engineering, mathematics and physical sciences graduates who wish to specialise in the maritime engineering science sector. Read more

This MSc will suit engineering, mathematics and physical sciences graduates who wish to specialise in the maritime engineering science sector. The core modules are particularly relevant to the Advanced Materials theme of this course.

Introducing your degree

Maritime Engineering Science is an MSc course designed for graduates, or similarly qualified, with an engineering, scientific or mathematical background, who desire to pursue a career in maritime sector. An introductory module is provided at the start to give students the fundamental knowledge necessary for them to succeed in the course. The masters course in Maritime Engineering Science / Advanced Materials enables the students to specialise in the in-depth study of engineering materials in addition to core naval architecture subject areas.

Overview

This course will enable you to develop a fundamental understanding of maritime engineering. Core modules are particularly relevant to the advanced materials theme where you will explore composites, titanium and aluminium and understand their selection and engineering for maritime applications.

The year is divided into two semesters. Each semester, in addition to a set of specialist modules, you will also have opportunity to select from a range of option modules including marine structures, finite element analysis and composite engineering design. You will also learn the broader principles of marine safety, environmental engineering and management.

The last four months will put your newly developed knowledge into practice. You will complete a major research project and take advantage of our many facilities, including a state-of-the-art Transportation Systems Research Laboratory and wind tunnel complex to support your experimental work.

View the specification document for this course

Career Opportunities

The maritime sector provides many and varied career opportunities in engineering and project management related roles. Maritime Engineering Science graduates are in strong demand with good starting salaries and excellent career progression opportunities.

Our graduates work across many different organisations. The Solent region around Southampton is the main UK hub for the maritime sector with organisations such as Lloyd’s Register, Carnival, BMT Nigel Gee, Maritime and Coastguard agency and many others based nearby. Organisations such BAE Systems, QinetiQ and Babcock support primarily the defence sector and employ a good number of our graduates. The offshore and marine renewable developments are offering excellent prospects both to work in the UK (locally, London or Aberdeen) or worldwide in places such as Singapore, Houston or Perth, etc.



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