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Take advantage of one of our 100 Master’s Scholarships to study Chemical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Chemical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

Key Features of MSc in Chemical Engineering

The MSc Chemical Engineering course is built upon the wide range of research in chemical engineering at Swansea University. This includes engineering applications of nanotechnology, bioengineering, biomedical engineering, cell and tissue engineering, chemical engineering, colloid science and engineering, desalination, pharmaceutical engineering, polymer engineering, rheology, separation processes, transport processes, and water and wastewater engineering.

The MSc Chemical Engineering research project provides an opportunity to work with a member of academic staff in one of the above, or related, area of research. The project may also involve collaboration with industry.

The taught component of the MSc Chemical Engineering course covers specific areas of advanced chemical engineering as well as the complex regulations that are found in the engineering workplace. It also provides an opportunity for the development of personal and transferable skills such as project planning, communication skills, and entrepreneurship.

As a student on the Master's course in Chemical Engineering, you will advance your technical knowledge, which can lead to further research or a career in chemical engineering.

Modules

Modules on the MSc Chemical Engineering course typically include:

Complex Fluids and Rheology
Entrepreneurship for Engineers
Colloid and Interface Science
Communication Skills for Research Engineers
Water and Wastewater Engineering
Membrane Technology
Environmental Analysis and Legislation
Optimisation
Desalination
Polymers: Properties and Design
Principles of Nanomedicine
Nanoscale Structures and Devices
Pollutant Transport by Groundwater Flows
MSc Research Practice
MSc Dissertation - Chemical Engineering

Accreditation

The MSc Chemical Engineering at Swansea University is accredited by the Institution of Chemical Engineers (IChemE).

The MSc Chemical Engineering degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Links with Industry

One of the major strengths of Chemical Engineering at Swansea University is the close and extensive involvement with local, national and international engineering companies. The companies include:

Acordis
Astra Zeneca
Avecia
BP Chemicals
Bulmers
Dow Corning
GlaxoSmithKline
Nestle
Murco
Phillips 66
Unilever
Valero

Swansea staff have research links with local, national, and international companies. An industrial advisory board, consisting of eight industrialists from a range of chemical engineering backgrounds, ensure our courses maintain their industrial relevance.

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Careers

The demand for Chemical Engineering graduates remains excellent with the highest starting salaries out of all engineering disciplines.

Chemical engineers find employment in a variety of public and private sector industries, applying the principles of chemical engineering to health, energy, food, the environment, medicine, petrochemicals and pharmaceuticals.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

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Take advantage of one of our 100 Master’s Scholarships to study Tissue Engineering and Regenerative Medicine at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Tissue Engineering and Regenerative Medicine at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

Every day we are hearing of ground breaking advances in the field of tissue engineering which offer tremendous potential for the future of regenerative medicine and health care. Staff at Swansea University are active in many aspects of tissue engineering.

Key Features of Tissue Engineering and Regenerative Medicine

We are actively researching many aspects of tissue engineering including the following areas:

- Characterisation and control of the stem cell niche
- Mechanical characterisation of stem cells and tissues
- Production of novel scaffolds for tissue engineering
- Electrospinning of scaffold materials
- Cartilage repair and replacement
- Bone repair and replacement
- The application of nanotechnology to regenerative medicine
- Wound healing engineering
- Reproductive Immunobiology
- Bioreactor design

As an MSc By Research Tissue Engineering and Regenerative Medicine student, you will join one of the teams at Swansea University working in tissue engineering and use state of the art research equipment within the Centre for NanoHealth, a collaborative initiative between the College of Engineering and Swansea University Medical School.

The MSc by Research in Tissue Engineering and Regenerative Medicine typically lasts one year full-time, two to three years part-time. This is an individual research project written up in a thesis of 30,000 words.

Aim of Tissue Engineering and Regenerative Medicine programme

The aim of this MSc by Research in Tissue Engineering and Regenerative Medicine is to provide you with a solid grounding within the field of tissue engineering and its application within regenerative medicine.

This will be achieved through a year of research in a relevant area of tissue engineering identified after discussion with Swansea academic staff. Working with two academic supervisors you will undertake a comprehensive literature survey which will enable the formulation of an experimental research programme.

As a student on the MSc by Research Tissue Engineering and Regenerative Medicine course, you will be given the relevant laboratory training to undertake the research program. The research will be written up as a thesis that is examined. You will also be encouraged to present your work in the form of scientific communications such as journals and conference poster presentation.

The MSc by Research in Tissue Engineering and Regenerative Medicine will equip you with a wealth of research experience and knowledge that will benefit your future career in academia or the health care industries.

Recent MSc by Research theses supervised in the area of Tissue Engineering at Swansea University include:

- Quality assurance of human stem cell/primary cell bank
- The development of electrospinning techniques for the production of novel tissue engineering scaffolds.
- The incorporation of pulsed electromagnetic fields into wound dressings.
- The application of pulsed electromagnetic fields for improved wound healing.
- The use of nanoparticles in the control of bacterial biofilms in chronic wounds.
- The control of bacterial adhesion at surfaces relevant to regenerative medicine.
- The production of micro-porous particles for bone repair

Facilities

The £22 million Centre for Nanohealth is a unique facility linking engineering and medicine, and will house a unique micro-nanofabrication clean room embedded within a biological research laboratory and with immediate access to clinical research facilities run by local NHS clinicians.

Links with industry

The academic staff of the Medical Engineering discipline have always had a good relationship with industrial organisations. The industrial input ranges from site visits to seminars delivered by clinical contacts.

The close proximity of Swansea University to two of the largest NHS Trusts in the UK outside of London also offers the opportunity for collaborative research.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

World-leading research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

Highlights of the Engineering results according to the General Engineering Unit of Assessment:

Research Environment at Swansea ranked 2nd in the UK
Research Impact ranked 10th in the UK
Research Power (3*/4* Equivalent staff) ranked 10th in the UK

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Take advantage of one of our 100 Master’s Scholarships to study Chemical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Chemical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

From authoring definitive text books on chemical engineering to finding solutions to the world's water shortages, Swansea University has a proud tradition of delivering pioneering innovative process engineering solutions. As we have a wide range of research in chemical engineering, Swansea University provides an excellent base for your research as an MSc by Research student in Chemical Engineering.

Key Features of MSc by Research in Chemical Engineering

There is a wide range of research in chemical engineering at Swansea University. This includes:

Membrane separation
Biochemical engineering
Biomanufacturing
Engineering applications of nanotechnology
Bioengineering, biomedical engineering
Cell and tissue engineering
Colloid science and engineering
Desalination
Pharmaceutical engineering
Polymer engineering
Rheology
Separation processes
Transport processes
Water and wastewater engineering

The MSc by Research in Chemical Engineering at Swansea University provides an opportunity to work with a member of academic staff in one of the above, or related, area of research.

The MSc by Research in Chemical Engineering typically lasts one year full-time, two to three years part-time. This is an individual research project written up in a thesis of 30,000 words.

Links with industry

One of the major strengths of Chemical Engineering at Swansea University is the close and extensive involvement with local, national and international engineering companies. The companies include:

Acordis
Astra Zeneca
Avecia
BP Chemicals
Bulmers
Dow Corning
GlaxoSmithKline
Nestle
Murco
Phillips 66
Unilever
Valero

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Swansea University has resources specific to Chemical Engineering.

Research

Research in Chemical Engineering at Swansea is located within the Systems and Process Engineering Research Centre which has a number of focused research groups including the Centre for Water Advanced Technologies and Environmental Research (CWATER), the Centre for Complex Fluids Processing and the Multidisciplinary Nanotechnology Centre.

The Centre for Water Advanced Technologies and Environmental Research (CWATER) is an internationally leading centre of excellence for the development of advanced technologies in water treatment. The Centre benefits from world-leading expertise in the areas of desalination and membrane technologies for water treatment.

The Centre for Complex Fluids Processing is internationally recognised for its leading and innovative research on the processing of complex fluids which is a major feature of modern industry. Such fluids are extremely diverse in origin and composition - ranging, for example, from fermentation broths and food products to inks and mineral slurries. However, underlying this diversity are certain properties that must be understood if the processing is to be effective and efficient. These include flow behaviour in process equipment, how the components of the fluid determine its overall properties and how individual components may be selectively separated.

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

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Located within a European Centre of Excellence for Tissue engineering, and based on Keele University’s local hospital campus, the MSc in Cell and Tissue Engineering provides support and development to enhance your career within this rapidly expanding field. Read more

Overview

Located within a European Centre of Excellence for Tissue engineering, and based on Keele University’s local hospital campus, the MSc in Cell and Tissue Engineering provides support and development to enhance your career within this rapidly expanding field. The multidisciplinary environment enables close interaction with leading academics and clinicians involved in cutting-edge, and clinically transformative research.

Course Director: Dr Paul Roach ()

Studying Cell and Tissue Engineering at Keele

Our MSc Cell and Tissue Engineering programme has tracked alongside the strongly emergent global Regenerative Medicine industry and will prepare you for an exciting future within a range of medical engineering areas, be that in academic or industrial research, medical materials, devices, or therapeutics sectors, or in the clinical arena. The modular structure to the course enables flexibility and personalisation to suit your career aspirations, build upon strengths and interests and develop new understanding in key topics. The selection of modules on offer is professionally accredited by the Institute for Physics and Engineering in Medicine.

Graduate destinations for our students could include: undertaking further postgraduate study and research (PhD); pursuing a university-based, academic research career; providing technical consultancy for marketing and sales departments within industry; working within biomedical, biomaterials, therapeutic and regenerative medicine industries or working for a governmental regulatory agency for healthcare services and products.

See the website https://www.keele.ac.uk/pgtcourses/cellandtissueengineering/

‌The course provides support from the basics of human anatomy and physiology, through to development of novel nanotechnologies for healthcare. Due to the teaching and research involvement of clinical academic staff within the department, there are exciting opportunities to be exposed to current clinical challenges and state-of-the-art developments. Clinical visits and specialist seminars are offered and students will be able to select dissertation projects that span fundamental research to clinical translation of technologies – a truly ‘bench to bedside’ approach.

Learning and teaching methods include lectures and demonstrations from medical and engineering specialists, practical classes using state-of-the-art facilities and seminars with leading national and international researchers. Full-time study will see the course completed in 12 months; part-time study will allow you to complete it over two years.

About the department

Now delivered through the Keele Medical School and the Research Institute for Science and Technology in Medicine, the course dates as far back as 1999, when it was established in partnership with Biomedical Engineering and Medical Physics at the University Hospital. Most teaching now takes place in the Guy Hilton Research Centre, a dedicated research facility located on the hospital campus. The medical school is one of the top-ranked in the UK, and the research institute has an international reputation for world-leading research.

The centre was opened in 2006 and offers state-of-the-art equipment for translational research including newly-developed diagnostic instruments, advanced imaging modalities and additive manufacturing facilities. Its location adjacent to the university hospital ensures that students experience real-world patient care and the role that technology plays in that. Students also have access to advanced equipment for physiological measurement, motion analysis and functional assessment in other hospital and campus-based laboratories. The School embraces specialists working in UHNM and RJAH Orthopaedic Hospital Oswestry, covering key medical and surgical subspecialties.

The course runs alongside its sister course, the MSc in Biomedical Engineering, and an EPSRC-MRC funded Centre for Doctoral Training, ensuring a stimulating academic environment for students and many opportunities for engaging with further study and research.

Course Content

The aim of the course is to provide multidisciplinary Masters level postgraduate training in Cell and Tissue Engineering to prepare students for future employment in healthcare, industrial and academic environments. This involves building on existing undergraduate knowledge in basic science or engineering and applying it to core principles and current issues in medicine and healthcare.

Specifically, the objectives of the course are to:
- provide postgraduate-level education leading to professional careers in Cell and Tissue Engineering in industry, academia and a wide range of healthcare establishments such as medical organisations, medical research institutions and hospitals;

- provide an opportunity for in-depth research into specialist and novel areas of Biomaterials, and Cell and Tissue Engineering;

- expose students to the clinically translational environment within an active medical research environment with hands-on practical ability and supporting knowledge of up-to-date technological developments at the forefront of the field;

- introduce students to exciting new fields such as regenerative medicine, nanotechnology and novel devices for physiological monitoring and diagnostics.

Teaching and Learning Methods

The course is taught through subject-centred lectures and seminars, supported by tutorials and practical exercises. Collaborative learning and student-centred learning are also adopted giving widespread opportunity for group work and individual assignments. Students are required to conduct extensive independent study, and this is supported by full access to two libraries, online journal access and a suite of dedicated computers for exclusive use by MSc students on the course. In addition, students are supported by the guidance of a personal tutor within the department, as well as having access to university-wide support services. This includes English language support where appropriate.

Assessment

Modules will be assessed by a mixture of assessment methods, including lab reports, essays, and presentations, and final examination. This ensures the development of a range of transferrable employability skills such as time management and planning, written and verbal communication and numeracy as well as technical and subject-specific knowledge. The project dissertation forms a major component of the student’s assessed work.

Additional Costs

Apart from additional costs for text books, inter-library loans and potential overdue library fines we do not anticipate any additional costs for this postgraduate programme.

Find information on Scholarships here - http://www.keele.ac.uk/studentfunding/bursariesscholarships/

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Have you ever wondered how the latest life science discoveries - such as a novel stem cell therapy - can move from the lab into commercial scale production?… Read more
Have you ever wondered how the latest life science discoveries - such as a novel stem cell therapy - can move from the lab into commercial scale production? Would you like to know whether it is possible to produce bio-polymers (plastics) and biofuels from municipal or agricultural waste? If you are thinking of a career in the pharma or biotech industries, the Biochemical Engineering MSc could be the right programme for you.

Degree information

Our MSc programme focuses on the core biochemical engineering principles that enable the translation of advances in the life sciences into real processes or products. Students will develop advanced engineering skills (such as bioprocess design, bioreactor engineering, downstream processing), state-of-the-art life science techniques (such as molecular biology, vaccine development, microfluidics) and essential business and regulatory knowledge (such as management, quality control, commercialisation).

Three distinct pathways are offered tailored for graduate scientists, engineers, or biochemical engineers. Students undertake modules to the value of 180 credits. The programme offers three different pathways (for graduate scientists, engineers, or biochemical engineers) and consists of core taught modules (120 credits) and a research or design project (60 credits).

Core modules for graduate scientists
-Advanced Bioreactor Engineering
-Bioprocess Synthesis and Process Mapping
-Bioprocess Validation and Quality Control
-Commercialisation of Bioprocess Research
-Fluid Flow and Mixing in Bioprocesses
-Heat and Mass Transfers in Bioprocesses
-Integrated Downstream Processing
-Mammalian Cell Culture and Stem Cell Processing

Core modules for graduate engineers
-Advanced Bioreactor Engineering
-Bioprocess Validation and Quality Control**
-Cellular Functioning from Genome to Proteome
-Commercialisation of Bioprocess Research
-Integrated Downstream Processing
-Mammalian Cell Culture and Stem Cell Processing
-Metabolic Processes and Regulation
-Structural Biology and Functional Protein Engineering
-Bioprocess Microfluidics*
-Bioprocess Systems Engineering*
-Bioprocessing and Clinical Translation*
-Cell Therapy Biology*
-Industrial Synthetic Biology*
-Sustainable Bioprocesses and Biorefineries*
-Vaccine Bioprocess Development*

*Core module for graduate biochemical engineers; **core module for both graduate engineers and graduate biochemical engineers

Research project/design project
All MSc students submit a 10,000-word dissertation in either Bioprocess Design (graduate scientists) or Bioprocess Research (graduate engineers and graduate biochemical engineers).

Teaching and learning
The programme is delivered through a combination of lectures, tutorials, and individual and group activities. Guest lectures delivered by industrialists provide a professional and social context. Assessment is through unseen written examinations, coursework, individual and group project reports, individual and group oral presentations, and the research or design project.

Careers

The rapid advancements in biology and the life sciences create a need for highly trained, multidisciplinary graduates possessing technical skills and fundamental understanding of both the biological and engineering aspects relevant to modern industrial bioprocesses. Consequently, UCL biochemical engineers are in high demand, due to their breadth of expertise, numerical ability and problem-solving skills. The first destinations of those who graduate from the Master's programme in biochemical engineering reflect the highly relevant nature of the training delivered.

Approximately three-quarters of our graduates elect either to take up employment in the relevant biotechnology industries or study for a PhD or an EngD, while the remainder follow careers in the management, financial or engineering design sectors.

Top career destinations for this degree:
-Mechanics of Material, Imperial College London
-PhD Biochemical Engineering, University College London (UCL)
-Bio-Pharmaceutical Engineer, GSK (GlaxoSmithKline)
-Associate Consultant, PwC
-Genetics Technician, Chinese Academy Of Sciences

Employability
The department places great emphasis on its ability to assist its graduates in taking up exciting careers in the sector. UCL alumni, together with the department’s links with industrial groups, provide an excellent source of leads for graduates. Over 1,000 students have graduated from UCL with graduate qualifications in biochemical engineering at Master’s or doctoral levels. Many have gone on to distinguished and senior positions in the international bioindustry. Others have followed independent academic careers in universities around the world.

Why study this degree at UCL?

UCL was a founding laboratory of the discipline of biochemical engineering, established the first UK department and is the largest international centre for bioprocess teaching and research. Our internationally recognised MSc programme maintains close links with the research activities of the Advanced Centre for Biochemical Engineering which ensure that lecture and case study examples are built around the latest biological discoveries and bioprocessing technologies.

UCL Biochemical Engineering co-ordinates bioprocess research and training collaborations with more than a dozen UCL departments, a similar number of national and international university partners and over 40 international companies. MSc students directly benefit from our close ties with industry through their participation in the Department’s MBI® Training Programme.

The MBI® Training Programme is the largest leading international provider of innovative UCL-accredited short courses in bioprocessing designed primarily for industrialists. Courses are designed and delivered in collaboration with 70 industrial experts to support continued professional and technical development within the industry. Our MSc students have the unique opportunity to sit alongside industrial delegates, to gain deeper insights into the industrial application of taught material and to build a network of contacts to support their future careers.

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The Engineering faculties of the Universiteit Gent and Vrije Universiteit Brussel organize the interuniversitary Master of Biomedical Engineering and this in a close collaboration with the Medical faculties of both universities. Read more

About the programme

The Engineering faculties of the Universiteit Gent and Vrije Universiteit Brussel organize the interuniversitary Master of Biomedical Engineering and this in a close collaboration with the Medical faculties of both universities. As a result of recent evolutions towards internationalization, we also offer a complete English master program in biomedical engineering. Both the Dutch and English masters are two-year programs and lead to a joint degree from UGent and VUB. Students study either in Ghent or in Brussels upon their own choice.

Tackle complex problems in biology, medicine and health sciences

Biomedical Engineering is a branch of Engineering where students acquire knowledge and skills which can be applied to tackle complex problems in biology, medicine and health sciences. The biomedical engineer herein strives towards a solution in balance with technological, economical and ethical constraints.

Learning outcomes

Graduated students master the fundamentals of current biomedical engineering and have a thorough knowledge of the basic concepts and an overview of the main applications in various fields of biomedical engineering (medical imaging, medical signal processing, medical physics, medical device technology, tissue engineering, biomaterials...). The graduated student has acquired the necessary research skills which allow him or her to independently analyze and solve a problem, and recognizes the importance of permanent learning in a continuously evolving domain.

Work in multidsciplinary teams:
The biomedical engineer is trained to work in multidisciplinary teams (influx of students with different bachelor backgrounds, lecturers from various faculties and scientific domains, multi-disciplinary projects) and has the required communication skills.

Awareness of ethical and socio-medical aspects:
The biomedical engineer is aware of the ethical and socio-economic aspects of biomedical engineering and healthcare, and of the social responsibility of a master in engineering.

Career possibilities:
In this master's course, knowledge and skills in all fields in biomedical engineering will be given, so when you finished the Master's programme, you can be employed as generalist, and you will also be specialised in one particular field of biomedical engineering.

As a student, you are able to select any field within biomedical engineering. You will be trained to work in interdisciplinary project teams, composed of engineers and medical specialists. To prepare further for interdisciplinary teams, students and scholars are treated as equals. To train for working in a European setting, you will get knowledge in the health care situation in several countries in Europe, and you will be trained in cultural differences between European countries.

In summary, the goal of this course is to acquire the ability to:
- work in interdisciplinary (engineering – medical) teams
- work in international and thus intercultural (European) teams
- communicate effectively with experts in (bio)medicine and technology
- perform fundamental research in Biomedical Engineering.
- design innovative devices to improve diagnostics and treatment of patients
- follow a post-Master’s training in Biomedical Engineering
- perform a PhD study
- train continuously (life-long-learning)

Curriculum

Available on http://www.vub.ac.be/en/study/biomedical-engineering/programme

The programme consists of 120 credits, evenly distributed over 4 semesters of each 12 weeks. The specific part of the master involves six basic courses for a total of 30 credits (Quantitative cell biology, Modelling of Physiological Systems, From Genome to Organism, Biomechanics, Bio-electronics and Biomaterials) and 42 credits dedicated to specialist courses in biomedical engineering (Biomedical Imaging, Neuromodulation and Imaging, Medical Physics, Medical Equipment, Biomedical Product Development, Artificial Organs: Technology and Design, Health Care Organization and Informatics, Human and Environment, Safety and Regulations* and Seminars: Innovations in Biomedical Engineering). The programme is further complemented with a master thesis (24 credits) and elective courses for a total of 24 credits.

Internships and Project Work

Students are encouraged to do an internship with a company or hospital in Belgium or abroad during the summer holiday period. Internships can be valorised in the curriculum, with an internship of 4 weeks accounting for an elective course of 3 credits, and an internship of minimally 6 weeks accounting for 6 credits. A maximum of 6 credits is allowed. In addition, students can opt for the elective 3 credit course “Multidisciplinary Biomedical Project” during which they can work on an assignment or a project.

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See the Department website - http://www.rit.edu/kgcoe/program/sustainable-engineering-0. Sustainable engineering refers to the integration of social, environmental, and economic considerations into product, process, and energy system design methods. Read more
See the Department website - http://www.rit.edu/kgcoe/program/sustainable-engineering-0

Sustainable engineering refers to the integration of social, environmental, and economic considerations into product, process, and energy system design methods. Additionally, sustainable engineering encourages the consideration of the complete product and process lifecycle during the design effort. The intent is to minimize environmental impacts across the entire lifecycle while simultaneously maximizing the benefits to social and economic stakeholders. The master of engineering in sustainable engineering is multidisciplinary and managed by the industrial and systems engineering department.

The program builds on RIT’s work in sustainability research and education and offers students the flexibility to develop tracks in areas such as renewable energy systems, systems modeling and analysis, product design, and engineering policy and management. The program is offered on campus, and available on a full- or part-time basis.

Educational objectives

The program is designed to accomplish the following educational objectives:

- Heightened awareness of issues in areas of sustainability (e.g., global warming, ozone layer depletion, deforestation, pollution, ethical issues, fair trade, gender equity, etc.).

- Clear understanding of the role and impacts of various aspects of engineering (design, technology, etc.) and engineering decisions on environmental, societal, and economic problems. Particular emphasis is placed on the potential trade-offs between environmental, social, and economic objectives.

- Strong ability to apply engineering and decision-making tools and methodologies to sustainability-related problems.

- Demonstrated capacity to distinguish professional and ethical responsibilities associated with the practice of engineering.

Plan of study

Technical in nature, the program equips engineers with the tools they need to meet the challenges associated with delivering goods, energy, and services through sustainable means. In addition to basic course work in engineering and classes in public policy and environmental management, students are required to complete a capstone project directly related to sustainable design challenges impacting society. Many of these projects can be incorporated into sustainability themed research by RIT faculty in the areas of fuel-cell development, life-cycle engineering, and sustainable process implementation.

Students must successfully complete a total of 36 credit hours through course work and a capstone project. This program is designed to be completed in three semesters.

Curriculum

- First Year

Fundamentals of Sustainable Engineering
Engineering of Systems I
Renewable Energy Systems
Lifecycle Assessment
Engineering Elective

- Second Year

Engineering Elective
Social Context Elective
Technology Elective
Engineering Capstone

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Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Read more
Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Nanoscience and technology research, ranging from nanostructured-materials to nanoelectronics, covers diverse areas in many disciplines, such as medicine and healthcare, aeronautics and space, environmental studies and energy, biotechnology and agriculture, national security and education. A joint postgraduate program in Nanoscience and Technology, initiated by the Schools of Science and Engineering, can offer long-term support to our ongoing research and training as well as to the development of technology and to commercialization efforts. Because of the diverse, multidisciplinary nature of Nanotechnology, its research and training can be best integrated into different disciplines. The aim of the concentration is to equip students with the necessary knowledge in the areas on which they wish to focus on.

Given the above developments, the School of Engineering has introduced the Nanotechnology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Electronic and Computer Engineering and Mechanical Engineering. This allows students to enroll in a particular discipline and pursue a focused-study on a specific area of Nanotechnology or Nanoscience.

The Nanotechnology Concentration is open exclusively to School of Engineering research postgraduates. Students must enroll in one of the following research degree programs prior to their registration for the Nanotechnology Concentration:
-MPhil/PhD in Chemical and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Mechanical Engineering

Research Foci

The research foci of Nanotechnology falls into the following disciplines:

Chemical and Biomolecular Engineering
Study of nanocatalysts, nanocomposite and nanoporous materials, nanomaterials for environmental applications, atmospheric nanoparticle pollutants, usage of nano-sized magnetic particles and nano-electrocatalysts, morphology/property relationship of polymers at nanoscale, bio-functionalized nanoparticles for diagnostics and biosensing, nanocarriers for drug delivery and nanomaterials for tissue engineering, and nano-biomaterials for treatment of industrial effluents.

Civil and Environmental Engineering
Development of iron-based nanoparticles for the removal of heavy metals from groundwater and industrial wastewater, polymeric nanocomposites for the surface coating of concrete structures, and fate, transport, transformation and toxicity of manufactured nanomaterials in water.

Electronic and Computer Engineering
Design, fabrication, and characterization of compound semiconductor-based nano-electronic devices, integration of compound semiconductor-based nano-electronic devices on silicon, modeling of nano-CMOS devices, nanoscale transistors, nanoelectromechanical system (NEMS), nanosize photo-alignment layers, nanoelectronics, nanophotonics, nanoelectronic devices design and fabrication, and system-on-chip and embedded system designs using nanotechnologies.

Mechanical Engineering
Nano precision machining, nanofibers, carbon nanotubes, graphene and organoclay nanoparticles, nanoindentation, applications of nano-particles for printable electronics and nano composites; integrated nano bubble actuator, nanosclae fluid-surface interaction, multiscale mechanics, nanoscale gas transport, micro/nanomechanics; molecular dynamic simulations, thermal interface material; micro fuel cell, and nano-structured materials for lithium ion battery electrodes.

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Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Read more
Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Nanoscience and technology research, ranging from nanostructured-materials to nanoelectronics, covers diverse areas in many disciplines, such as medicine and healthcare, aeronautics and space, environmental studies and energy, biotechnology and agriculture, national security and education. A joint postgraduate program in Nanoscience and Technology, initiated by the Schools of Science and Engineering, can offer long-term support to our ongoing research and training as well as to the development of technology and to commercialization efforts. Because of the diverse, multidisciplinary nature of Nanotechnology, its research and training can be best integrated into different disciplines. The aim of the concentration is to equip students with the necessary knowledge in the areas on which they wish to focus on.

Given the above developments, the School of Engineering has introduced the Nanotechnology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Electronic and Computer Engineering and Mechanical Engineering. This allows students to enroll in a particular discipline and pursue a focused-study on a specific area of Nanotechnology or Nanoscience.

The Nanotechnology Concentration is open exclusively to School of Engineering research postgraduates. Students must enroll in one of the following research degree programs prior to their registration for the Nanotechnology Concentration:
-MPhil/PhD in Chemical and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Mechanical Engineering

Research Foci

The research foci of Nanotechnology falls into the following disciplines:

Chemical and Biomolecular Engineering
Study of nanocatalysts, nanocomposite and nanoporous materials, nanomaterials for environmental applications, atmospheric nanoparticle pollutants, usage of nano-sized magnetic particles and nano-electrocatalysts, morphology/property relationship of polymers at nanoscale, bio-functionalized nanoparticles for diagnostics and biosensing, nanocarriers for drug delivery and nanomaterials for tissue engineering, and nano-biomaterials for treatment of industrial effluents.

Civil and Environmental Engineering
Development of iron-based nanoparticles for the removal of heavy metals from groundwater and industrial wastewater, polymeric nanocomposites for the surface coating of concrete structures, and fate, transport, transformation and toxicity of manufactured nanomaterials in water.

Electronic and Computer Engineering
Design, fabrication, and characterization of compound semiconductor-based nano-electronic devices, integration of compound semiconductor-based nano-electronic devices on silicon, modeling of nano-CMOS devices, nanoscale transistors, nanoelectromechanical system (NEMS), nanosize photo-alignment layers, nanoelectronics, nanophotonics, nanoelectronic devices design and fabrication, and system-on-chip and embedded system designs using nanotechnologies.

Mechanical Engineering
Nano precision machining, nanofibers, carbon nanotubes, graphene and organoclay nanoparticles, nanoindentation, applications of nano-particles for printable electronics and nano composites; integrated nano bubble actuator, nanosclae fluid-surface interaction, multiscale mechanics, nanoscale gas transport, micro/nanomechanics; molecular dynamic simulations, thermal interface material; micro fuel cell, and nano-structured materials for lithium ion battery electrodes.

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Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Read more
Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Nanoscience and technology research, ranging from nanostructured-materials to nanoelectronics, covers diverse areas in many disciplines, such as medicine and healthcare, aeronautics and space, environmental studies and energy, biotechnology and agriculture, national security and education. A joint postgraduate program in Nanoscience and Technology, initiated by the Schools of Science and Engineering, can offer long-term support to our ongoing research and training as well as to the development of technology and to commercialization efforts. Because of the diverse, multidisciplinary nature of Nanotechnology, its research and training can be best integrated into different disciplines. The aim of the concentration is to equip students with the necessary knowledge in the areas on which they wish to focus on.

Given the above developments, the School of Engineering has introduced the Nanotechnology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Electronic and Computer Engineering and Mechanical Engineering. This allows students to enroll in a particular discipline and pursue a focused-study on a specific area of Nanotechnology or Nanoscience.

The Nanotechnology Concentration is open exclusively to School of Engineering research postgraduates. Students must enroll in one of the following research degree programs prior to their registration for the Nanotechnology Concentration:
-MPhil/PhD in Chemical and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Mechanical Engineering

Research Foci

The research foci of Nanotechnology falls into the following disciplines:
Chemical and Biomolecular Engineering
Study of nanocatalysts, nanocomposite and nanoporous materials, nanomaterials for environmental applications, atmospheric nanoparticle pollutants, usage of nano-sized magnetic particles and nano-electrocatalysts, morphology/property relationship of polymers at nanoscale, bio-functionalized nanoparticles for diagnostics and biosensing, nanocarriers for drug delivery and nanomaterials for tissue engineering, and nano-biomaterials for treatment of industrial effluents.

Civil and Environmental Engineering
Development of iron-based nanoparticles for the removal of heavy metals from groundwater and industrial wastewater, polymeric nanocomposites for the surface coating of concrete structures, and fate, transport, transformation and toxicity of manufactured nanomaterials in water.

Electronic and Computer Engineering
Design, fabrication, and characterization of compound semiconductor-based nano-electronic devices, integration of compound semiconductor-based nano-electronic devices on silicon, modeling of nano-CMOS devices, nanoscale transistors, nanoelectromechanical system (NEMS), nanosize photo-alignment layers, nanoelectronics, nanophotonics, nanoelectronic devices design and fabrication, and system-on-chip and embedded system designs using nanotechnologies.

Mechanical Engineering
Nano precision machining, nanofibers, carbon nanotubes, graphene and organoclay nanoparticles, nanoindentation, applications of nano-particles for printable electronics and nano composites; integrated nano bubble actuator, nanosclae fluid-surface interaction, multiscale mechanics, nanoscale gas transport, micro/nanomechanics; molecular dynamic simulations, thermal interface material; micro fuel cell, and nano-structured materials for lithium ion battery electrodes.

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Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Read more
Nanoscience and technology have become one of the most visible and fast growing multidisciplinary research areas. Nanoscience and technology research, ranging from nanostructured-materials to nanoelectronics, covers diverse areas in many disciplines, such as medicine and healthcare, aeronautics and space, environmental studies and energy, biotechnology and agriculture, national security and education. A joint postgraduate program in Nanoscience and Technology, initiated by the Schools of Science and Engineering, can offer long-term support to our ongoing research and training as well as to the development of technology and to commercialization efforts. Because of the diverse, multidisciplinary nature of Nanotechnology, its research and training can be best integrated into different disciplines. The aim of the concentration is to equip students with the necessary knowledge in the areas on which they wish to focus on.

Given the above developments, the School of Engineering has introduced the Nanotechnology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Electronic and Computer Engineering and Mechanical Engineering. This allows students to enroll in a particular discipline and pursue a focused-study on a specific area of Nanotechnology or Nanoscience.

The Nanotechnology Concentration is open exclusively to School of Engineering research postgraduates. Students must enroll in one of the following research degree programs prior to their registration for the Nanotechnology Concentration:
-MPhil/PhD in Chemical and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Mechanical Engineering

Research Foci

The research foci of Nanotechnology falls into the following disciplines:
Chemical and Biomolecular Engineering
Study of nanocatalysts, nanocomposite and nanoporous materials, nanomaterials for environmental applications, atmospheric nanoparticle pollutants, usage of nano-sized magnetic particles and nano-electrocatalysts, morphology/property relationship of polymers at nanoscale, bio-functionalized nanoparticles for diagnostics and biosensing, nanocarriers for drug delivery and nanomaterials for tissue engineering, and nano-biomaterials for treatment of industrial effluents.

Civil and Environmental Engineering
Development of iron-based nanoparticles for the removal of heavy metals from groundwater and industrial wastewater, polymeric nanocomposites for the surface coating of concrete structures, and fate, transport, transformation and toxicity of manufactured nanomaterials in water.

Electronic and Computer Engineering
Design, fabrication, and characterization of compound semiconductor-based nano-electronic devices, integration of compound semiconductor-based nano-electronic devices on silicon, modeling of nano-CMOS devices, nanoscale transistors, nanoelectromechanical system (NEMS), nanosize photo-alignment layers, nanoelectronics, nanophotonics, nanoelectronic devices design and fabrication, and system-on-chip and embedded system designs using nanotechnologies.

Mechanical Engineering
Nano precision machining, nanofibers, carbon nanotubes, graphene and organoclay nanoparticles, nanoindentation, applications of nano-particles for printable electronics and nano composites; integrated nano bubble actuator, nanosclae fluid-surface interaction, multiscale mechanics, nanoscale gas transport, micro/nanomechanics; molecular dynamic simulations, thermal interface material; micro fuel cell, and nano-structured materials for lithium ion battery electrodes.

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The Department of Mechanical and Aerospace Engineering (MAE) is one of the leading MAE departments in Asia. It offers rigorous academic and professional training in a wide range of areas, including both traditional and cutting-edge topics in energy, mechanics, advanced materials, nano/biotechnology, and manufacturing. Read more
The Department of Mechanical and Aerospace Engineering (MAE) is one of the leading MAE departments in Asia. It offers rigorous academic and professional training in a wide range of areas, including both traditional and cutting-edge topics in energy, mechanics, advanced materials, nano/biotechnology, and manufacturing.

The aim of the MAE Department is to produce high quality MAE graduates with competitive academic training, technology leadership, and/or entrepreneurship.

The Department has 26 full-time faculty members. Many of them are internationally renowned scholars in their fields. There are about 150 research postgraduate students. The MAE Department is also equipped with many state-of-the-art laboratory facilities. Our faculty and postgraduate students conduct research at the frontier of mechanical and aerospace engineering and collaborate closely with local industry.

The MPhil program focuses on strengthening students' background in the fundamentals of mechanical and aerospace engineering and exposing them to the environment of academic research and development. Students are required to undertake coursework and complete a thesis to demonstrate their competence in engineering research.

Research Foci

The Department's research concentrates on energy and environmental engineering, mechanics and materials, and mechatronics and manufacturing. Research covers several major areas:

Solid Mechanics and Dynamics
These are two of the fundamental pillars of Mechanics research. The Department has a diverse faculty with expertise in these fields. Research activities range from applied to theoretical problems, and have a marked multidisciplinary nature. They involve: applied mathematics, solid mechanics, nonlinear dynamics, computations, solid state physics, material science and experiments for various kinds of solid materials/systems and mechanical behaviors. Faculty members work on problems of both static and dynamic natures with different types of evolutions. These problems also involve multi-field coupling on different scales of time and length, from micro-second to long time creep processes and from a very small carbon nanotube or a cell to macroscopic scale composite materials and electro-mechanical devices/systems.

Materials Technology
Materials engineering focuses on characterizing and processing new materials, developing processes for controlling their properties and their economical production, generating engineering data necessary for design, and predicting the performance of products. Research topics include: smart materials, biomaterials, thin films, composites, fracture and fatigue, residual life assessment, materials issues in electronic packaging, materials recycling, plastics flow in injection molding, advanced powder processing, desktop manufacturing, and instrumentation and measurement techniques.

Energy/Thermal Fluid and Environment Engineering
Research in energy, thermal/fluids and environmental engineering includes fuel cells and batteries, advanced renewable energy storage systems, thermoelectric materials and devices, nanoscale heat and mass transfer, transport in multicomponent and multiphase systems, innovative electronics cooling systems, energy efficient buildings, and contaminant transport in indoor environments.

Design and Manufacturing Automation
These elements lie at the heart of mechanical engineering in which engineers conceive, design, build, and test innovative solutions to "real world" problems. Research is being conducted in the areas of geometric modeling, intelligent design and manufacturing process optimization, in-process monitoring and control of manufacturing processes, servosystem control, robotics, mechatronics, prime-mover system control, sensor technology and measurement techniques, and bio-medical systems design and manufacturing.

Microsystems and Precision Engineering
Micro ElectroMechanical Systems (MEMS) is a multidisciplinary research field which has been making a great impact on our daily life, including various micro sensors used in personal electronics, transportation, communication, and biomedical diagnostics. Fundamental and applied research work is being conducted in this area. Basic micro/nanomechanics, such as fluid and solid mechanics, heat transfer and materials problems unique to micro/nanomechanical systems are studied. New ideas to produce microsystems for energy, biomedicine and nanomaterials, micro sensors and micro actuators are explored. Technology issues related to the micro/nanofabrication of these devices are being addressed.

Aerospace Engineering
Aerospace engineering is a major branch of engineering concerned with research, development, manufacture and operation of aircraft and spacecraft. Within the aerospace engineering group, fundamental and applied research is being conducted in areas such as aerodynamics, aeroacoustics, aircraft and engine noise and performance, combustion dynamics, thermoacoustics, atomization and sprays, and aircraft design and optimization. Advanced experimental facilities and high-fidelity computational methods are being developed and used. The group boasts two world-class anechoic wind tunnels for aerodynamics and aeroacoustics research, and is home to a major research center on aircraft noise technology.

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Sustainable engineering refers to the integration of social, environmental, and economic considerations into product, process, and energy system design methods. Read more
Sustainable engineering refers to the integration of social, environmental, and economic considerations into product, process, and energy system design methods. Additionally, sustainable engineering encourages the consideration of the complete product and process lifecycle during the design effort. The intent is to minimize environmental impacts across the entire lifecycle while simultaneously maximizing the benefits to social and economic stakeholders. The MS in sustainable engineering is multidisciplinary and managed by the industrial and systems engineering department.

The program builds on RIT’s work in sustainability research and education and offers students the flexibility to develop tracks in areas such as renewable energy systems, systems modeling and analysis, product design, and engineering policy and management. Course work is offered on campus and available on a full- or part-time basis.

Educational objectives

The program is designed to accomplish the following educational objectives:

- Heighten awareness of issues in areas of sustainability (e.g., global warming, ozone layer depletion, deforestation, pollution, ethical issues, fair trade, gender equity, etc.).

- Establish a clear understanding of the role and impact of various aspects of engineering (design, technology, etc.) and engineering decisions on environmental, societal, and economic problems. Particular emphasis is placed on the potential trade-offs between environmental, social, and economic objectives.

- Strong ability to apply engineering and decision-making tools and methodologies to sustainability-related problems.

- Demonstrate a capacity to distinguish professional and ethical responsibilities associated with the practice of engineering.

Plan of study

Technical in nature, the program equips engineers with the tools they need to meet the challenges associated with delivering goods, energy, and services through sustainable means. In addition to basic course work in engineering and classes in public policy and environmental management, students are required to complete a research thesis directly related to sustainable design challenges impacting society. Many thesis projects support the sustainability-themed research being conducted by RIT faculty in the areas of fuel-cell development, life-cycle engineering, and sustainable process implementation.

Students must successfully complete a total of 33 semester credit hours of course work comprised of five required core courses; two graduate engineering electives in an area of interest such as energy, modeling, manufacturing and materials, transportation and logistics, or product design and development; one social context elective; one environmental technology elective; two semesters of Graduate Seminar I, II (ISEE-795, 796); and a thesis. This research-oriented program is designed to be completed in two years.

Curriculum

- First Year

Fundamentals of Sustainable Engineering
Engineering of Systems I
Renewable Energy Systems
Graduate Seminar I
Lifecycle Assessment
Engineering Electives
Graduate Seminar II

- Second Year

Technology Elective
Social Context Elective
Research and Thesis

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The Faculty of Engineering runs a multi-disciplinary postgraduate course entitled Sustainable Engineering with a number of different themes, one of which is offshore renewable energy. Read more

Why this course?

The Faculty of Engineering runs a multi-disciplinary postgraduate course entitled Sustainable Engineering with a number of different themes, one of which is offshore renewable energy.

This flexible programme combines study in specialist, advanced engineering technologies underpinned with training in sustainability. The programme has been developed with direct industrial involvement to provide you with a solid understanding of modern, sustainable engineering. As well as gaining an understanding of how sustainable engineering applies to offshore renewable energy, this programme will also provide you with key transferable skills to aid your employability.

The course is designed for experienced or newly qualified engineers in:
- Naval Architecture
- Marine Engineering
- Mechanical Engineering
- Civil Engineering
- Electrical Engineering or related disciplines

The Department of Naval Architecture, Ocean & Marine Engineering, a leading institution in Scotland, offers excellent teaching and research facilities in naval architecture, ocean and marine engineering, which expands your career opportunities in naval architecture, marine, offshore oil and gas industry.

See the website https://www.strath.ac.uk/courses/postgraduatetaught/sustainableengineeringoffshorerenewableenergy/

You’ll study

Studying at least three generic classes will meet the key requirements to attain Chartered Engineer status.

You must take three specialist classes if you are studying for the Postgraduate Certificate and up to five if you are studying for a Postgraduate Diploma or MSc.

Successful completion of six classes leads to the award of a Postgraduate Certificate.

- Group project
You’ll work with a group of students from different pathways of the Sustainable Engineering programme. You’ll produce sustainable solutions to real-life industry problems. This project will include site visits, field trips and progress reports to industry partners.
Successful completion of eight modules and the group project leads to the award of a Postgraduate Diploma.

- Individual project
MSc students will study a selected topic in depth and submit a thesis.
Successful completion of eight classes, the group project and an individual project leads to the award of an MSc.

Facilities

We have excellent teaching facilities including:
- Catalina - our departmental racing yacht
- Kelvin Hydrodynamics Lab - the largest ship-model experiment tank in any UK university
- Towing/wave tank exclusively for teaching purposes
- Marine engine laboratory
- Hydrogen fuel cell laboratory
- Cutting-edge computer facilities
- Industry standard software

Studying at least three generic modules will meet the key requirements to attain Chartered Engineer status.

Student competitions

Naval Architecture, Ocean & Marine Engineering supports and promotes students in various competitions and awards, from cash bursaries for top performing students to the highest of awards from international organisations.

In recent years our students have been triumphant in the following high profile competitions:
- Science, Engineering & Technology Student of the Year (SET Awards)
- Best Maritime Technology Student (SET Awards)
- Double winner of BP’s Ultimate Field Trip Competition
- Strathclyder of the Year

Pre-Masters preparation course

The Pre-Masters Programme is a preparation course for international students (non EU/UK) who do not meet the entry requirements for a Masters degree at University of Strathclyde. The Pre-Masters programme provides progression to a number of degree options.

To find out more about the courses and opportunities on offer visit isc.strath.ac.uk or call today on +44 (0) 1273 339333 and discuss your education future. You can also complete the online application form. To ask a question please fill in the enquiry form and talk to one of our multi-lingual Student Enrolment Advisers today.

Learning & teaching

There are two teaching periods (semesters) of 12 weeks each. The first semester is usually from the beginning of October and the second semester starts at the end of January.
Some of the second semester subjects are taught over eight weeks so that you can devote as much time as possible to your individual project work.
Each year about 15 experts from the industry give talks and seminars on wide-ranging topics. Industrial visits are made to a variety of companies.
You’re required to attend an induction prior to the start of the course.

Assessment

There are two types of method for module assessment. One is course work assessment only, the other is examination assessment. For examined modules the final assessment mark consists of 30-40% course work and 60-70% examination

Careers

- Where are they now?
100% of our graduates are in work or further study.*

Job titles include:
- Graduate Design Engineer
- Project Engineer
- Renewable Energy Consultant
- Thermal Performance Engineer

Employers include:
- Arup
- Eaton
- Esteyco Energua
- Granite Services International
- Moorfield International
- Mott Macdonald

*Based on the results of the national Destinations of Leavers from Higher Education Survey (2010/11 and 2011/12).

Find information on Scholarships here http://www.strath.ac.uk/search/scholarships/index.jsp

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The programme provides the student with an Engineering education applied to medical and biological issues, through deep basic and specialist training in various biomedical topics. Read more

Mission and goals

The programme provides the student with an Engineering education applied to medical and biological issues, through deep basic and specialist training in various biomedical topics. The educational path is intended to train students for designing equipment, devices, materials and procedures and for a correct introduction, development and management of biomedical technologies inside Companies and Health Structures, as well as freelance. The peculiar multidisciplinary structure of the programme allows developing a strong knowledge in electronics and informatics, mechanical, chemical and material engineering and promotes the integration of technical studies with life science disciplines (biology, physiology and medicine).

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

Career opportunities

Graduated biomedical engineers find employment for the design, development and commercialization of biomedical devices, as well as in the pharmaceutical sector. Career opportunities are found: 1) in manufacturing companies which are active on health-care market with systems for prevention, diagnostics, therapy and rehabilitation; 2) in public and private hospitals for the management of health technologies; 3) in medical plant and equipment service companies; 4) in specialised biomedical laboratories; 5) in biomedical research 6) as freelance.
For a more specific training in scientific research in the area, a Ph.D. in Bioengineering is available.

The programme has 4 advised paths (besides the possibility to develop a personal path with some constraints):
- Clinical Engineering
- Electronic Technologies
- Biomechanics and Biomaterials
- Cell, Tissue and Biotechnology Engineering

Presentation

See http://www.polinternational.polimi.it/uploads/media/Biomedical_Engineering_01.pdf
This postgraduate programme provides students with an engineering education applied to medical and biological issues. The educational path is intended to train students in the design of biomedical equipment, devices, materials and procedures and to offer a correct introduction to the management of biomedical technologies in companies and health bodies. The peculiar multidisciplinary structure of the programme allows the development of a strong knowledge in electronics and informatics, in mechanical, chemical and material engineering and promotes the integration of technical studies with life science disciplines like biology, physiology and
medicine. The programme is taught in English.

Subjects

Four specializations available:
- Clinical Engineering
- Electronic Technologies
- Biomechanics and Biomaterials
- Cell, Tissue and Biotechnology Engineering

Mandatory courses for all areas:
- mathematical and digital methods for engineering
- bioengineering of the motor system
- mechanics of biological structures
- bioengineering of autonomic control and respiratory systems
- biofluid dynamics
- biomechanical design
- biomachines (with laboratory)
- biomaterials
- endoprostheses
- biomimetics and tissue engineering
- biotechnological applications and bioreactors
- design of life support systems
- laboratory of tissue characterization
- laboratory of biomaterials + lab. of instrumental analysis
- laboratory of biofluid dynamics
- laboratory of biomechanical design
- computational biomechanics laboratory

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

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

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

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