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Masters Degrees (Polymer Technology)

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This programme provides professional training in polymer science and technology for graduates of science, engineering and technology subjects. Read more
This programme provides professional training in polymer science and technology for graduates of science, engineering and technology subjects.

Lectures are supplemented by an extensive variety of laboratory exercises, spanning chemical and physical characterisation, and compounding and processing technology experiments on pilot-scale laboratory equipment.

Core study areas include polymer science, polymer process engineering, plastics and composites applications, polymer properties, polymer characterisation, polymerisation and polymer blends, plastics processing technology and a project.

Optional study areas include plastics processing technology, rubber compounding and processing, adhesive bonding, and sustainable use of materials.

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

Programme modules

Full-time Modules:
Core Modules
- Polymer Science (SL)
- Polymer Process Engineering (SL)
- Plastics and Composites Applications (SL)
- Polymer Properties (SL)
- Polymer Characterisation (OW)
- Polymerisation and Polymer Blends (SL)
- MSc Project

Optional Modules
- Biomaterials (SL)
- Rubber Compounding and Processing (OW)
- Adhesive Bonding (OW)

Part-time Modules:
Core Modules
- Polymer Science (DL)
- Plastics and Composites Applications (DL)
- Polymer Properties (DL)
- Polymer Characterisation (OW)
- Polymerisation and Polymer Blends (DL)
- Plastics Processing Technology (OW)
- MSc Project

Optional Modules
- Rubber Compounding and Processing (OW or DL)
- Adhesive Bonding (OW)
- Sustainable use of Materials (OW or DL)

Alternative modules:*
- Design with Engineering Materials (DL)
- Polymer Process Engineering (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 plastics, rubber, chemical and additives industries and packaging.
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 who are interested in research stay with us to study for a PhD.

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 90% 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/polymer-science-tech/

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This course trains graduates with a chemistry background specifically for a career as a polymer or biopolymer scientist. Read more
This course trains graduates with a chemistry background specifically for a career as a polymer or biopolymer scientist. The content reflects global interest in sustainably-derived polymers which are increasing in demand in a variety of applications including food and beverages, pharmaceutical, cosmetics, personal care, paints and inks.

Our specialist course will equip you with the knowledge to understand the behaviour of both naturally occurring and synthetic water soluble polymers at the molecular level, and how this influences their bulk behaviour. Lectures are reinforced and expanded by study of real-life polymer systems in the laboratory.

You'll learn about the vital roles played by polymers in a rage of products, gain knowledge of biopolymer modification, polymer synthesis and a range of specialist characterisation techniques. During your research project you'll work with specialists from manufacturing industries and perform a programme of experiments designed to help you develop your skills.

Key Course Features

-You will learn about the vital roles played by polymers in a diverse range of high value products – e.g in mayonnaise, sun tan lotion, wound gels, liquid pharmaceuticals, paper, ink, water based paints and flotation aids in mining to name just a few.
-You’ll gain first-hand knowledge of biopolymer modification, polymer synthesis, and a wide range of specialist characterisation techniques.
-In your research project you will interface with specialists from manufacturing industries and undertake a programme of experiments designed to develop the skills you want to learn.
-Through case studies and your research project you will learn how to apply acquired knowledge in real world industrial scenarios, leading the way to success in subsequent employment.

What Will You Study?

The course comprises 6 x 20 credit modules of taught content and a 60 credit research project. The taught element is delivered by a varied programme including lectures, seminars, practical classes and may be studied on a full time or part time basis to suit you. There is a strong emphasis on development of hands-on practical skills using a wide variety of advanced instrumentation.

TAUGHT MODULES
-Advanced Materials Science
-Chemistry & Technology of Water Soluble Polymers
-Formulation Science
-Polymer Characterisation Case Study
-Structure and Function of Industrial Biopolymers

The lectures and workshops are designed to train you in understanding polymer molecules themselves, and the way they interact with each other, and with solvents, surfactants, particles and surfaces.

You will:
-Study the basic principles of polymer characterisation through a range of analytical techniques including FT-IR, UV-vis, NMR, ESR and fluorescence spectroscopy.
-Master the measurement of molar mass distribution using gel permeation chromatography with multi angle laser light scattering (GPC-MALLS), and gel electrophoresis.
-Use particle sizing techniques such as digital imaging and laser diffraction to measure aggregates, flocs and emulsion droplets.
-Discover Green Chemistry - exploring a whole range of biopolymers extracted from natural resources….including antimicrobial polymers from shellfish waste, gelling agents from seaweed, and oligosaccharides from locally grown grasses.
-Learn about man-made polymers and importantly, chemically modified biopolymers.
-Measure the viscosity and rheology of liquid formulations and see how this can be interpreted to yield structural information on thickened systems and gels.
-A module in research methods provides training in all aspects of undertaking research, from project management, through data analysis and statistics to communicating your results and writing your dissertation to ensure you are well equipped to undertake your project.

RESEARCH PROJECT
The course culminates in an industry-focussed Research Project. For full-time students this may be partly or wholly undertaken within a local manufacturing company. For part-time students the project provider may be your current employer. The Research Project gives you the opportunity to undertake a piece of novel research, and will often be based around solving a polymer application /characterisation problem for the project provider. It allows you to put into practice the knowledge and skills gained in the taught elements of the course.

Because of the individual nature of the research projects, no two projects are the same. Below are some of the titles of previous research projects undertaken by previous Masters students in our department:
-Aspects of Adhesive Bonding of Low Energy Polymers
-The effects of Surfactants on the Rheological Properties of Hydrophobically Modified Cellulose
-Extensional Rheometry and Dynamic Light Scattering of Telechelic Associating Polymer Solutions
-Simple chemical syntheses of polymer/silver nanocomposites
-Phase separation of Gum Arabic and Hyaluronan in Aqueous Solution
-Shear and extensional Rheology of Electron Beam (EB) Curable Paint

The information listed in this section is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal academic framework review, so may be subject to change.

Assessment and Teaching

Assessment of the taught modules is intended to allow the learner to demonstrate skills that cover the entire breadth of the programme aims – knowledge and understanding, key practical skills, intellectual skills in planning experiments/interpreting data and communication of information in writing and verbally.

The research project is examined by a final dissertation.

Career Prospects

The EU is the leading chemical production area in the world and the chemical industry is the UK's largest manufacturing export sector.

MSc Polymer and Biopolymer Science combines delivery of key theoretical knowledge with hands-on application in extraction, modification and testing of polymers / biopolymers.

You’ll learn how to develop experiments at bench scale through to processes at pilot and manufacturing scale. A Masters degree in Polymer & Biopolymer Science from Glyndwr University gives you the skills employers are looking for.

You'll be ready to step confidently into a world of manufacturing with a wealth of information and skills to offer. The course provides excellent career opportunities across a wide range of industrial sectors. Graduates can expect to obtain a research and development position in areas related to biomedical devices, pharmaceutical formulation, food and beverages, petroleum recovery, agrochemicals, functional polymers/speciality chemicals, inks, paints and coatings or cosmetics and personal care products.

The course also provides a direct route to doctoral study, for those wishing to undertake further research training or pursue an academic career.

The Careers & Zone at Wrexham Glyndŵr University is there to help you make decisions and plan the next steps towards a bright future. From finding work or further study to working out your interests, skills and aspirations, they can provide you with the expert information, advice and guidance you need.

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The MSc Polymer Science and Technology is a brand new course that commences in Autumn 2012. This course will capitalise on research strengths that already exist within the School of Engineering and Materials Science, particularly within the area of polymers and composites. Read more
The MSc Polymer Science and Technology is a brand new course that commences in Autumn 2012. This course will capitalise on research strengths that already exist within the School of Engineering and Materials Science, particularly within the area of polymers and composites. The course will focus on polymers and polymer composites and will conclude with an independent research project related to these areas.

Modules will prepare students for independent research while also increasing their knowledge of the structure and behaviours of different polymer materials. You will also learn how to decide what materials are the most suitable for the design different products, depending on the environmental impact that results. There will be an emphasis on the various different types of materials processes that are currently used as well as the techniques that are still being developed.

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Polymers and polymer composites are increasingly important in our everyday life and can be found everywhere around us. At the same time, more and more high-performance speciality polymers and polymer nanocomposites have been developed for advanced engineering, plastic electronics, biomedical applications. Read more

About the course

Polymers and polymer composites are increasingly important in our everyday life and can be found everywhere around us. At the same time, more and more high-performance speciality polymers and polymer nanocomposites have been developed for advanced engineering, plastic electronics, biomedical applications.

Bringing together expertise from the Department of Materials Science and Engineering and the Department of Chemistry, and further supported by the Polymer Centre, the UK’s largest single-university academic network in the field of polymers, this course will provide you with a thorough understanding of advanced topics on polymer and composite science and engineering.

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

Polymer Characterization and Analysis; Polymer Materials Science and Engineering; Polymer Chemistry; Biopolymers and Biomaterials; research project.

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This course is designed with industry in mind. We have also partnered with Engineering Materials and Physics to encompass the breadth of modern polymer science and technology. Read more

About the course

This course is designed with industry in mind. We have also partnered with Engineering Materials and Physics to encompass the breadth of modern polymer science and technology. You’ll become the kind of high-calibre polymer science graduate needed to develop new products and processes in a variety of industries.

Through a combination of theory and practice, we’ll teach you about polymer synthesis, physics, characterisation and the latest developments in polymer research. When you design and conduct your own extended research project, you can look in more detail at the areas you’re most interested in and learn how to communicate your science to the chemical community.

Your future

Our graduates are highly valued in the chemical and pharmaceutical sector. They work all over the world for companies including AkzoNobel, Amgen, AstraZeneca, Corus, Dow Chemicals, GSK, Smith and Nephew and Syngenta. Many move on to PhD study, then careers in research or teaching.

Chemistry is vital to the way we live. It helps power industry and drive economic growth. Polymer science contributes to advances in everything from biology to engineering and medicine. As a researcher in industry or academia you could be involved in work that improves lives and changes the way we see the world.

Learn from world-class research

Top-quality research directly informs our teaching. The 2014 Research Excellence Framework (REF) rates 98 per cent of our work world-class or internationally excellent. You’ll learn about the very latest developments from experts in theory and spectroscopy, synthesis, analytical science, chemical biology and materials.

Labs, equipment and training

We’ll train you to use our modern analytical instrumentation. We have NMR spectroscopy, mass spectrometry, x-ray crystallography, polymer characterisation methods and advanced microscopy. We also have a team of technicians to assist with spectroscopic services. There are labs for molecular biology, protein chemistry, polymer/colloid synthesis and materials characterisation.

Core modules

Fundamental Polymer Chemistry; The Physics of Polymers; Biopolymers and Biomaterials; Polymer Characterisation and Analysis; Research and Presentation Skills and Polymer Laboratory Skills; Extended Research Project.

Examples of optional modules

Smart Polymers and Polymeric Materials; Polymers with Controlled Structures; Design and Manufacture of Composites; Polymer Fibre Composite Materials; Macromolecules at Interfaces and Structured Organic Films; Electronics and Photonics.

Teaching and assessment

We use a mixture of lectures, practicals, workshops and individual research projects. The optional modules in the second semester enable you to specialise in two specific areas of polymer science. You can also tailor your research project to your particular interests.

For all taught modules, written exams contribute 75 per cent towards your final grade. The other 25 per cent comes from continuous assessment, which might include essays on specialised topics or assessed workshops. You also produce a 15,000-word dissertation based on your research project.

Your research project

This can be based in an academic group at the University, or in industry. If it’s industry- based, the topic is usually suggested by the company you’re working with. You may be expected to liaise closely with the company to organise your project.

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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 90% 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/

Read less
This course draws upon the internationally recognised research within the school in areas such as 3D woven preforms (for use in the aerospace and other transportation sectors), nanocomposites and technical textiles. Read more
This course draws upon the internationally recognised research within the school in areas such as 3D woven preforms (for use in the aerospace and other transportation sectors), nanocomposites and technical textiles. The team which delivers the course also has a wealth of industrial experience built from collaborations with key companies including Rolls Royce, Bombardier and Airbus.

Key benefits

- Accredited by the Institution of Mechanical Engineers (IMechE) on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

- Accredited by the Institution of Engineering and Technology on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

- Part-time students can undertake work based learning modules.

- Students can apply for exemptions for specific modules based on prior learning.

Visit the website: https://www.ulster.ac.uk/course/msc-advanced-composites-and-polymers-ft-jn

Course detail

- Description -

This programme provides education and training in advanced composites and polymers and their intelligent application in industry.

- Course format and assessment -

Full-time students take four modules per semester for semesters 1 and 2 and then undertake the dissertation during the summer. Part-time students generally take two modules per semester but this can be altered as required. Part-time students attend one day per week during term time and some of the modules run in the evening.

Core modules:

• Composite engineering
• Polymer technology
• Process product optimisation
• Research Methods & Facilities

Students can then tailor the course to their needs and interests by selecting from a wide range of optional modules.

The course is delivered through lectures, tutorials and laboratory classes and is supported with extensive online content. The small class sizes provide an excellent learning environment and the material is assessed thorough formal examinations, coursework, class tests and presentations.

Career options

Upon successful completion of the programme students will be more employable, particularly within the industry. Another important opportunity for MSc students is the academic career and/or research career through a PhD programme such as those offered in the Engineering Research Institute (ERI) which hosts the MSc programme.

How to apply: https://www.ulster.ac.uk/apply/how-to-apply#pg

Why Choose Ulster University ?

1. Over 92% of our graduates are in work or further study six months after graduation.
2. We are a top UK university for providing courses with a period of work placement.
3. Our teaching and the learning experience we deliver are rated at the highest level by the Quality Assurance Agency.
4. We recruit international students from more than 100 different countries.
5. More than 4,000 students from over 50 countries have successfully completed eLearning courses at Ulster University.

Flexible payment

To help spread the cost of your studies, tuition fees can be paid back in monthly instalments while you learn. If you study for a one-year, full-time master’s, you can pay your fees up-front, in one lump sum, or in either five* or ten* equal monthly payments. If you study for a master’s on a part-time basis (e.g. over three years), you can pay each year’s fees up-front or in five or ten equal monthly payments each year. This flexibility allows you to spread the payment of your fees over each academic year. Find out more by visiting https://www.ulster.ac.uk/apply/fees-and-finance/postgraduate

Scholarships

A comprehensive range of financial scholarships, awards and prizes are available to undergraduate, postgraduate and research students. Scholarships recognise the many ways in which our students are outstanding in their subject. Individuals may be able to apply directly or may automatically be nominated for awards. Visit the website: https://www.ulster.ac.uk/apply/fees-and-finance/scholarships

English Language Tuition

CELT offers courses and consultations in English language and study skills to Ulster University students of all subjects, levels and nationalities. Students and researchers for whom English is an additional language can access free CELT support throughout the academic year: https://www.ulster.ac.uk/international/english-language-support

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The course is a suitable preparation for employment in the medical device sector and as preparation for PhD studies or research positions. Read more
The course is a suitable preparation for employment in the medical device sector and as preparation for PhD studies or research positions. The course draws upon the internationally recognised research with the school in areas such as Tissue Engineering, Bioceramics, Medical Electrodes and Drug Delivery. The course team also has a wealth of industrial experience and several medical device spin out companies have been established by the school.

Key benefits

- Accredited by the Institution of Engineering and Technology on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

Visit the website: https://www.ulster.ac.uk/course/msc-biomedical-engineering-ft-jn

- Part-time students who are in full-time employment will be able to gain credit for work-based activity in the work-based learning modules that are a feature of the programme.

- Students can apply for exemptions for specific modules based on prior learning.

Visit the website: https://www.ulster.ac.uk/course/msc-biomedical-engineering-pt-jn

Course detail

- Description -

The course has been designed to provide postgraduate education and training in the concepts and methods within Biomedical Engineering and their intelligent application to problems within industry and academic research.

- Purpose -

It will enable candidates to develop a comprehensive knowledge and understanding of scientific principles, theories and practice.

- Teaching and learning assessment -

The course is delivered through lectures, tutorials and laboratory classes and is supported with extensive online content. The small class sizes provide an excellent learning environment and the material is assessed thorough formal examinations, coursework, class tests and presentations.

Core module:

• Bioinstrumentation
• Biomaterials 1
• Tissue engineering
• Research Methods & Facilities Core modules
• Composite engineering • Polymer technology
• Process product optimisation
• Research Methods & Facilities

Students can then tailor the course to their needs and interests by selecting from a wide range of optional modules.

Career options

Upon successful completion of the programme students will be more employable, particularly within the industry. Another important opportunity for MSc students is the academic career and/or research career through a PhD programme such as those offered in the Engineering Research Institute (ERI) which hosts the MSc programme.

How to apply: https://www.ulster.ac.uk/apply/how-to-apply#pg

Why Choose Ulster University ?

1. Over 92% of our graduates are in work or further study six months after graduation.
2. We are a top UK university for providing courses with a period of work placement.
3. Our teaching and the learning experience we deliver are rated at the highest level by the Quality Assurance Agency.
4. We recruit international students from more than 100 different countries.
5. More than 4,000 students from over 50 countries have successfully completed eLearning courses at Ulster University.

Flexible payment

To help spread the cost of your studies, tuition fees can be paid back in monthly instalments while you learn. If you study for a one-year, full-time master’s, you can pay your fees up-front, in one lump sum, or in either five* or ten* equal monthly payments. If you study for a master’s on a part-time basis (e.g. over three years), you can pay each year’s fees up-front or in five or ten equal monthly payments each year. This flexibility allows you to spread the payment of your fees over each academic year. Find out more by visiting https://www.ulster.ac.uk/apply/fees-and-finance/postgraduate

Scholarships

A comprehensive range of financial scholarships, awards and prizes are available to undergraduate, postgraduate and research students. Scholarships recognise the many ways in which our students are outstanding in their subject. Individuals may be able to apply directly or may automatically be nominated for awards. Visit the website: https://www.ulster.ac.uk/apply/fees-and-finance/scholarships

English Language Tuition

CELT offers courses and consultations in English language and study skills to Ulster University students of all subjects, levels and nationalities. Students and researchers for whom English is an additional language can access free CELT support throughout the academic year: https://www.ulster.ac.uk/international/english-language-support

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The Masters of Research in Tissue Engineering for Regenerative Medicine (TERM) is a collaborative degree course that brings together interdisciplinary expertise from the Faculty of Biology, Medicine and Health and the Faculty of Science and Engineering. Read more
The Masters of Research in Tissue Engineering for Regenerative Medicine (TERM) is a collaborative degree course that brings together interdisciplinary expertise from the Faculty of Biology, Medicine and Health and the Faculty of Science and Engineering.

This course provides:
-Postgraduate-level training to equip students from biological, engineering and/or medical-related backgrounds with the specialist knowledge and research skills to pursue a career in the field of tissue engineering/regenerative medicine
-A primary focus on strategies to repair, replace and ultimately regenerate various tissues and organs to solve major clinical problems
-A comprehensive insight into topical issues including stem cells, polymer technology, surface fabrication and gene delivery
-Training for students to identify major clinical needs and formulate novel therapeutic solutions

Tissue engineering/regenerative medicine as a discipline shows enormous potential for future health and, economically, there is a national demand for specific interdisciplinary training in this area.

The University of Manchester has a vast research network in this field comprising international experts from multiple disciplines, and so is extremely well-placed to deliver a truly unique masters course of exceptional quality.

This programme has both taught and research components and is suitable for those with little or no previous research experience.

Career opportunities

After the course, many students will continue their studies and register for a PhD.

However, the programme is also of value to students wishing to progress in the pharmaceutical industry, biotechnology companies or specialist clinical training.

The masters is also ideal for MBChB intercalating students who wish to undertake directly channelled research training in the tissue engineering/regenerative medicine field.

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make sound judgements associated with engineering design for polymer based products by means of existing, new and emerging manufacturing processes. Read more
make sound judgements associated with engineering design for polymer based products by means of existing, new and emerging manufacturing processes. The course aims to ensure that graduates will be able to demonstrate self-direction and originality and are equipped with the appropriate knowledge to practise professionally and ethically in future employment roles.

Thus, the course will:

Address industry’s demand for graduates who can apply engineering design solutions for rapid and cost effective manufacture of discrete parts and tooling across the engineering sector

Develop the ability to research a range of subject areas within manufacturing, mechanical, materials science and engineering disciplines, underpinning the ability to act autonomously in planning and implementing tasks at a professional or equivalent level

Generate graduates capable of synthesising their detailed understanding of polymer engineering design and related material science in order to offer confident justified solutions to complex, unpredictable and open ended situations.

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Materials are substances or things from which something is or can be made. Technological development is often based on the development of new materials. Read more
Materials are substances or things from which something is or can be made. Technological development is often based on the development of new materials. Materials research plays an important part in solving challenging problems relating to energy, food, water, health and well-being, the environment, sustainable use of resources, and urbanisation.

An expert in materials research studies the chemical and physical bases of existing and new materials; their synthesis and processing, composition and structure, properties and performance. As an expert in materials research, your skills will be needed in research institutions, the technology industry (electronics and electrotechnical industry, information technology, mechanical engineering, metal industry, consulting), chemical industry, forest industry, energy industry, medical technology and pharmaceuticals.

This programme combines expertise from the areas of chemistry, physics and materials research at the University of Helsinki, which are ranked high in international evaluations. In the programme, you will focus on the fundamental physical and chemical problems in synthesising and characterising materials, developing new materials and improving existing ones. Your studies will concentrate on materials science rather than materials engineering.

Upon graduating from the programme you will have a solid understanding of the essential concepts, theories, and experimental methods of materials research. You will learn the different types of materials and will be able to apply and adapt theories and experimental methods to new problems in the field and assess critically other scientists’ work. You will also be able to communicate information in your field to both colleagues and laymen.

Depending on the study line you choose you will gain in-depth understanding of:
-The synthesis, processing, structure and properties of inorganic materials.
-Modelling methods in materials research.
-The structure and dynamics of biomolecular systems.
-The synthesis, structure and properties of polymers.
-Applications of materials research in industrial applications.
-The use of methods of physics in medicine.

The University of Helsinki will introduce annual tuition fees to foreign-language Master’s programmes starting on August 1, 2017 or later. The fee ranges from 13 000-18 000 euros. Citizens of non-EU/EEA countries, who do not have a permanent residence status in the area, are liable to these fees. You can check this FAQ at the Studyinfo website whether or not you are required to pay tuition fees: https://studyinfo.fi/wp2/en/higher-education/higher-education-institutions-will-introduce-tuition-fees-in-autumn-2017/am-i-required-to-pay-tuition-fees/

Programme Contents

In the programme, all teaching is based on the teachers’ solid expertise in the fundamental chemistry and physics of materials. All teachers also use their own current research in the field in their teaching.

Your studies will include a variety of teaching methods such as lectures, exercises, laboratory work, projects and summer schools.

In addition to your major subject, you can include studies in minor subjects from other programmes in chemistry, physics and computer science.

Selection of the Major

At the beginning of your studies you will make a personal study plan, with the help of teaching staff, where you choose your study line. This programme has the following six study lines representing different branches of materials research.

Experimental Materials Physics
Here you will study the properties and processing of a wide variety of materials using experimental methods of physics to characterise and process them. In this programme the materials range from the thin films used in electronics components, future fusion reactor materials, and energy materials to biological and medical materials. The methods are based on different radiation species, mostly X-rays and ion beams.

Computational Materials Physics
In this study line you will use computer simulations to model the structures, properties and processes of materials, both inorganic materials such as metals and semiconductors, and biological materials such as cell membranes and proteins. You will also study various nanostructures. The methods are mostly atomistic ones where information is obtained with atomic level precision. Supercomputers are often needed for the calculations. Modelling research is closely connected with the experimental work related to the other study lines.

Medical Physics
Medical physics is a branch of applied physics encompassing the concepts, principles and methodology of the physical sciences to medicine in clinics. Primarily, medical physics seeks to develop safe and efficient diagnosis and treatment methods for human diseases with the highest quality assurance protocols. In Finland most medical physicists are licensed hospital physicists (PhD or Phil.Lic).

Polymer Materials Chemistry
In this line you will study polymer synthesis and characterisation methods. One of the central questions in polymer chemistry is how the properties of large molecules depend on the chemical structure and on the size and shape of the polymer. The number of applications of synthetic polymers is constantly increasing, due to the development of polymerisation processes as well as to better comprehension of the physical properties of polymers.

Inorganic Materials Chemistry
Thin films form the most important research topic in inorganic materials chemistry. Atomic Layer Deposition (ALD) is the most widely studied deposition method. The ALD research covers virtually all areas related to ALD: precursor synthesis and characterisation, film growth and characterisation, reaction mechanism studies, and the first steps of taking the processes toward applications. The emphasis has been on thin film materials needed in future generation integrated circuits, but applications of ALD in energy technologies, optics, surface engineering and biomaterials are also being studied. Other thin film deposition techniques studied include electrodeposition, SILAR (successive ionic layer adsorption and reaction) and sol-gel. Nanostructured materials are prepared either directly (fibres by electrospinning and porous materials by anodisation) or by combining these or other templates with thin film deposition techniques.

Electronics and Industrial Applications
Sound and light are used both to sense and to actuate across a broad spectrum of disciplines employing samples ranging from red hot steel to smooth muscle fibres. Particular interest is in exploiting the link between the structure and mechanics of the samples. The main emphasis is on developing quantitative methods suitable for the needs of industry. To support these goals, research concentrates on several applied physics disciplines, the main areas being ultrasonics, photoacoustics, fibre optics and confocal microscopy.

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The modern society relies on the work of Chemical Engineers who develop and design the processes that make the useful products for the society by efficient use and management of resources including water and energy while controlling health and safety procedures and protecting the environment. Read more
The modern society relies on the work of Chemical Engineers who develop and design the processes that make the useful products for the society by efficient use and management of resources including water and energy while controlling health and safety procedures and protecting the environment.

Chemical Engineering provides essential tools based on the concept of sustainability and low carbon footprint for changing raw materials into useful products in a safe and cost effective way. Chemical Engineers understand how to alter the chemical, biochemical or physical state of a substance, to create everything from health care products (face creams, shampoo, perfume, drugs) to food (dairy products, cereals, agro-chemicals) and water (desalination for freshwater) to energy (petroleum to nuclear fuels).

Your study at MSc level at Bradford will be a foundation for life aimed at developing a deep understanding of advanced technical principles, analytical tools, and competence in their application together with a wide range of management, personal and professional skills. The course will provide you with essential tools based on the concept of sustainability and low carbon footprint for changing raw materials into useful products in a safe and cost effective way.

Why Bradford?

Flexibility of career path – Choice of three routes:
-Chemical Engineering - advanced chemical engineering and process technology skills for exciting and challenging careers in chemical and process industries
-Petroleum Engineering -matches the needs in different areas of oil and gas production and in medium/small operating and consulting companies
-Polymer Engineering - design and operation of processes to engineer materials with advanced properties leading to careers in diverse manufacturing sectors

Research Strengths - Internationally acclaimed research activities in the following areas:
-Chemical and Petrochemical Engineering
-Polymers
-Energy
-Water
-Pharmaceutical engineering
-Coating and advanced materials engineering

Rankings

Top Five: Chemical Engineering at the University of Bradford is ranked 5th in the UK in the Guardian University League Table 2017/

[[Modules
MSc Chemical & Petroleum Engineering (Chemical Engineering Background)
-Desalination Technology
-Materials & Manufacturing Processes
-Transport Phenomena
-Design Optimisation
-Computational Fluid Dynamics
-Upstream Production & Refinery Operations
-Research Skills
-Food & Pharmaceutical Processes Engineering
-Polymer Engineering
-Risk Management
-Engineering Computational Methods
-MSc Project

MSc Chemical & Petroleum Engineering (non-Chemical Engineering Background)
-Desalination Technology
-Transport Phenomena
-Chemical Engineering Practice
-Material & Manufacturing Processes
-Design Optimisation
-Computational Fluid Dynamics
-Upstream Production & Refinery Operations
-Research Skills
-Food & Pharmaceutical Processes Engineering
-Polymer Engineering
-Risk Management
-Engineering Computational Methods
-MSc Project

Career support and prospects

The University is committed to helping students develop and enhance employability and this is an integral part of many programmes. Specialist support is available throughout the course from Career and Employability Services including help to find part-time work while studying, placements, vacation work and graduate vacancies. Students are encouraged to access this support at an early stage and to use the extensive resources on the Careers website.

Discussing options with specialist advisers helps to clarify plans through exploring options and refining skills of job-hunting. In most of our programmes there is direct input by Career Development Advisers into the curriculum or through specially arranged workshops.

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Take your skills in chemistry further with a course that prepares you with the cutting-edge knowledge required for a career in the manufacturing or product development industries. Read more
Take your skills in chemistry further with a course that prepares you with the cutting-edge knowledge required for a career in the manufacturing or product development industries.

Formulation is a vital activity central to manufacturing in a wide range of industries. The course encompasses polymer and colloid science, building understanding of the physical and chemical interactions between multiple components in complex formulations, leading to a competitive advantage in product development and quality control.

You'll learn the trade secrets behind successful formulation,dealing with issues such as product stability, controlling flocculation, rheology and compatibility issues with multi-component systems. Whichever industry sector you're interested in working within, you'll develop the skills to deign formulations for a wealth of scenarios, for example food, cosmetics, pharmaceuticals and more.

Key Course Features

-You will develop skills to design formulations for a wealth of industrial scenarios - from food, cosmetics and personal care, pharmaceuticals, paper production, inks and coatings, oil drilling and mining to name just a few.
-In your research project you will interface with specialists from manufacturing industries and undertake a programme of experiments designed to develop the skills you want to learn.
-On this course you will learn the trade secrets behind successful formulation - dealing with issues such as product stability (stabilising emulsions and dispersions), controlling flocculation, rheology (flow properties, mouthfeel, gelation), and overcoming compatibility issues with multi component systems. You'll be introduced to modelling, new trends in processing and high throughput formulation.

What Will You Study?

The course comprises 6 x 20 credit modules of taught content and a 60 credit Research Project. The taught element is delivered by a varied programme including lectures, seminars, and practical classes and may be studied on a full time or part time basis to suit you.

There is a strong emphasis on development of hands-on practical skills using a wide variety of advanced instrumentation.

TAUGHT MODULES
-Advanced Materials Science
-Chemistry & Technology of Water Soluble Polymers
-Formulation Science
-Research Methods
-Structure and Function of Industrial Biopolymers

The lectures and workshops are designed to train you in understanding interactions between polymer, solvent, and surfactant molecules with particles and surfaces. You will:
-Review the range of formulation types found in various industrial sectors, and their components.
-Master analytical techniques used to optimise product formulation, including measurement of molar mass distribution using gel permeation chromatography with multi angle laser light scattering (GPC-MALLS) and particle sizing techniques such as digital imaging and laser diffraction (to measure aggregates, flocs and emulsion droplets)
-Discover Green Chemistry and eco-formulation- exploring a whole range of biopolymers extracted from natural resources….including antimicrobial polymers from shellfish waste, gelling agents from seaweed, and oligosaccharides from locally grown grasses.
-Learn about man-made polymers and importantly, chemically modified biopolymers.
-Measure the viscosity and rheology of liquid formulations and see how this can be interpreted to yield structural information on thickened systems and gels, and particulate systems including fillers, additives and dispersants.

A module in Research Methods provides training in all aspects of undertaking research, from project management, through data analysis and statistics to communicating your results and writing your dissertation to ensure you are well quipped to undertake your project.

RESEARCH PROJECT
The course culminates in an industry-focused Research Project. For full-time students this may be partly or wholly undertaken within a local manufacturing company. For part-time students the project provider may be your current employer. The Research Project gives you the opportunity to undertake a piece of novel research, and will often be based around solving a formulation problem for the project provider. It allows you to put into practice the knowledge and skills gained in the taught elements of the course.

Because of the individual nature of the research projects, no two projects are the same. Below are some of the titles of previous research projects undertaken by previous masters students in our department:
-Aspects of Adhesive Bonding of Low Energy Polymers
-The Effects of Surfactants on the Rheological Properties of Hydrophobically Modified Cellulose
-Extensional Rheometry and Dynamic Light Scattering of Telechelic Associating Polymer Solutions
-Simple chemical syntheses of polymer/silver nanocomposites
-Phase Separation of Gum Arabic and Hyaluronan in Aqueous Solution
-Shear and extensional Rheology of Electron Beam (EB) Curable Paint

The information listed in this section is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal academic framework review, so may be subject to change.

Assessment and Teaching

Assessment of the taught modules is intended to allow the learner to demonstrate skills that cover the entire breadth of the programme aims – knowledge and understanding, key practical skills, intellectual skills in planning experiments/interpreting data and communication of information in writing and verbally.

The research project is examined by a final dissertation.

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We have a long history of internationally recognized research in the study and development of new materials. Read more
We have a long history of internationally recognized research in the study and development of new materials. This course gives the possibility of working with and learning from expert researchers in the physics of materials in a friendly and vibrant research atmosphere provided by the international team of scientists at the Department of Physics.

This programme contains a combination of supervised research work, development of research skills and taught material. The programme involves a set of taught modules and an experimental or theoretical research project.

The theme of the project will be dedicated to one of the topical areas in physics of materials including graphene-based materials, thin film materials, shape memory compounds or nanomaterials or experimental study of properties of materials.

Core study areas mathematical methods for interdisciplinary sciences, research methods in physics, superconductivity and nanoscience, characterisation techniques in solid state physics, and a research project.

Optional study areas include polymer properties, polymer science, advanced characterisation techniques, simulation of advanced materials and processes, and materials modelling.

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

Programme modules

Compulsory Modules:
- Mathematical Methods for Interdisciplinary Sciences
- Research Methods in Physics
- Superconductivity and Nanoscience
- Research Project Part 1
- Research Project Part 2
- Characterisation Techniques in Solid State Physics

Optional Modules:
- Polymer Properties
- Polymer Science
- Advanced Characterisation Techniques
- Simulation of Advanced Materials and Processes
- Materials Modelling

Learning and teaching

Knowledge and understanding are acquired through lectures, tutorials, problem classes and guided independent study. Assessment in taught modules is by a combination of examination and coursework. The MSc includes a significant research project completed through guided independent study with a research supervisor.

Careers and further study

The aim of the course is to equip students with key skills they need for employment in industry, public service or academic research.

Why choose physics at Loughborough?

We are a community of approximately 170 undergraduates, 30 postgraduates, 16 full-time academic staff, seven support staff, and several visiting and part-time academic staff.

Our large research student population and wide international links make the Department a great place to work.

- Research
Our research strengths are in the areas of condensed matter and materials, with a good balance between theory and experiment.
The quality of our researchers is recognised internationally and we publish in highly ranked physics journals; one of our former Visiting Professors, Alexei Abrikosov, was awarded the 2003 Nobel Prize in Physics.

- Career Prospects
100% of our graduates were in employment and/or further study six months after graduating. They have gone on to work with companies such as BT, Nikon Metrology, Prysmian Group, Rutherford Appleton Laboratory ISIS and Smart Manufacturing Technology.

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

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1. Big Challenges being addressed by this programme – motivation. Human health and quality of life is one of the most critical challenges facing humanity. Read more

About the Course

1. Big Challenges being addressed by this programme – motivation

• Human health and quality of life is one of the most critical challenges facing humanity.
• The challenge is all the greater due to a rapidly increasing and rapidly aging global population that now exceeds 7 billion.
• Biomedical Engineering addresses these issues directly, with engineers innovating, analysing, designing and manufacturing new medical implants, devices and therapies for the treatment of disease, injuries and conditions of the human body, to restore health and improve quality of life.
• CNN lists Biomedical Engineering as No. 1 in the “Best Jobs in America” 2013.

2. Programme objectives & purpose

The objective of the programme is to generate graduates with a sound grounding in engineering fundamentals (analysis, design and problem solving), but who also have the multi-disciplinary breadth that includes knowledge of human biology and clinical needs and applications, to be able to make an immediate impact in the field on graduation, in either the academic research or medical technology industry domains. Ultimately the programme aims to generate the future leaders of the national and international medical technology industry, and of academic research and teaching in biomedical engineering.

3. What’s special about CoEI/NUIG in this area:

• NUI Galway pioneered the development of educational programmes in Biomedical Engineering in Ireland, introducing the country’s first bachelor’s degree in Biomedical Engineering in 1998, that was the first to achieve professional accreditation from Engineers Ireland in 2004, and at the graduate level with the Structured PhD programme in Biomedical Engineering and Regenerative Medicine (BMERM) in 2011.
• NUI Galway has been at the forefront of world-class research in biomedical engineering for over 20 years and has pioneered multi-disciplinary research in biomedical engineering and science, with the establishment of the National Centre for Biomedical Engineering Science (NCBES) in 1999, and up to the present day with the announcement of NUI Galway as the lead institution in a new Science Foundation Ireland funded Centre for Research in Medical Devices (CÚRAM).
• NUI Galway has a very close and deep relationship with the medical device industry locally, nationally and internationally, at many levels, from industry visits, guest lectures and student placements, up to major research collaborations.
• Many of our engineering graduates now occupy senior management and technical positions in the medical device industry nationally and internationally.

4. Programme Structure – ECTS weights and split over semester; core/elective, etc.:

• 90ECTS programme
• one full year in duration, beginning September and finishing August
• comprises:
- Foundational taught modules (20 ECTS)
- Advanced taught modules (40 ECTS)
- Research/Industry Project (30 ECTS).

5. Programme Content – module names

Sample Modules:

Advanced Finite Element Methods
Advanced Computational Biomechanics
Advanced Biomaterials
Mechanobiology
Bioinstrumentation Design
Medical and Surgical Practice
Stem Cells and Gene Therapy
Translational Medicine
Polymer Engineering
Advanced Engineering Statistics
Systems Reliability
Lean Systems
Research Methods for Engineers
Financial Management
Regulatory Affairs and Case Studies
Technology, Innovation and Entrepreneurship

6. Any special funding arrangements – e.g. Irish Aid

Comment (PMcH): CoEI scholarships a great idea.

7. Opportunity for number of Industrial & Research internships.

Students enrolled on this programme will have an opportunity to apply for a one-year post-graduation internship in either a related industry or research group in Ireland.

8. Testimonials.

“The Biomedical Engineering programme at NUI Galway has given me the fundamental engineering skills and multi-disciplinary background in biology and clinical application that I needed to be able to make an immediate impact in industry and to be able to design and develop new medical implants and devices. My graduate education through my PhD in bone biomechanics was also very important in this because I directly combined engineering and biological analysis techniques to better understand how stem cells generate new bone, showing me how biomedical engineers can play a critically important role in generating new knowledge on how the body works, and how new treatments can be developed for diseases and injuries, such as osteoporosis.” Evelyn Birmingham, BE Biomedical Engineering (2009), PhD Biomedical Engineering (2014), R&D Engineer, Medtronic Vascular, Galway.

For further details

visit http://nuigalway.ie/engineering-informatics/internationalpostgraduatestudents/

How to Apply:

Applications are made online via the Postgraduate Applications Centre (PAC): https://www.pac.ie
Please use the following PAC application code for your programme:

M.Sc. Biomedical Engineering - PAC code GYE24

Scholarships :

Please visit our website for more information on scholarships: http://www.nuigalway.ie/engineering-informatics/internationalpostgraduatestudents/feesandscholarships/

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