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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 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
Environmental Analysis and Legislation
Polymers: Properties and Design
Principles of Nanomedicine
Nanoscale Structures and Devices
Pollutant Transport by Groundwater Flows
MSc Research Practice
MSc Dissertation - Chemical Engineering
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.
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:
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.
Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.
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.
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.
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.
The Master of Science in Chemical Engineering programme is primarily aimed at applying chemical engineering principles to develop technical products and to design, control and improve industrial processes. Students also learn to take environmental and safety issues into account during all phases of the process.
Two guiding principles of sustainable development – the rational exploitation of resources and energy, and the application of the best available technology – are emphasised, as is the mantra “reduce, reuse, recycle”.
As a chemical engineering student, you will learn to think in a process-oriented manner and grasp the complexity of physico-chemical systems. Even more than other specialists, you will be asked to solve problems of a very diverse nature. Insights into processes at the nano and micro scale are fundamental for the development of new products and/or (mega-scale) technologies.
While students should have a foundational knowledge of chemistry, the underlying chemistry of the elements and components, their properties and mutual reactions are not the main focal points of the programme.
With a focus on process, product and environmental planet engineering, the programme does not only guarantee a solid chemical engineering background, it also focuses on process and product intensification, energy efficient processing routes, biochemical processes and product-based thinking rather than on the classical process approach.
The programme itself consists of an important core curriculum that covers the foundations of chemical engineering. The core curriculum builds on the basic knowledge obtained during the Bachelor’s. In this part of the programme, you will concentrate on both the classical and the emerging trends in chemical engineering.
Students also take up 9 credits from ‘Current trends in chemical engineering’-courses. These courses are signature courses for the Master’s programme and build on the research expertise present within the department. These courses encompass microbial process technology, process intensification, exergy analysis of chemical processes and product design.
The curriculum consists of a broad generic core, which is then strengthened and honed during the second year, when students select one of the three specialisations: product, process and environmental engineering.
This choice provides you with the opportunity to specialise to a certain extent. Since the emerging areas covered in the programme are considered to be the major challenges within the chemical and related industries, graduating in Leuven as a chemical engineer will give you a serious advantage over your European colleagues since you will be able to integrate new technologies within existing production processes.
During their Master’s studies, students are encouraged to take non-technical courses (general interest courses), organized for instance by other faculties (economics, social sciences, psychology…) in order to broaden their scope beyond mere technical courses.
An important aspect of the Master’s programme is the Master’s thesis. Assigning Master’s thesis topics to students is based on a procedure in which students select 5 preferred topics from a long list.
The Master’s programme highly values interactions with the chemical industry which is one of the most important pillars of the Flemish economy. As such, some courses are taught by guest professors from the industry.
One or two semesters of the programme can be completed abroad in the context of the ERASMUS+ programme. Additionally, you can apply for an industrial internship abroad through the departmental internship coordinator. These internships take place between the third Bachelor’s year and the first Master’s year, or between the two Master’s years.
The department also offers a new exchange programme with the University of Delaware (United States) and with the Ecole Polytechique in Montréal (Canada).
The faculty’s exchange programmes are complemented by the BEST network (Board of European Students of Technology). This student organisation offers the opportunity to follow short courses, usually organised in the summer months. The faculty also participates in various leading international networks.
You can find more information on this topic on the website of the Faculty website.
The chemical sector represents one of the most important economic sectors in Belgium. It provides about 90,000 direct and more than 150,000 indirect jobs. With a 53 billion euro turnover and a 35% share of the total Belgian export, the chemical sector is an indispensable part of the contemporary Belgian economy.
As a chemical engineer you will predominantly work in industrial branches involved in (the production of) bulk and specialty chemicals, oil and natural gas (petrochemical companies and refineries), non-ferrometallurgics, energy, waste treatment, food, cosmetics, pharmaceuticals and biotechnology. The following professional activities lie before you:
Apart from the traditional career options, your insight into complex processes will also be much appreciated in jobs in the financial and governmental sector, where chemical engineers are often employed to supervise industrial activities, to deliver permissions, and to compose regulations with respect to safety and environmental issues.
As self-employed persons, chemical engineers work in engineering offices or as consultants. Due to their often very dynamic personality, chemical engineers can also be successful as entrepreneurs.
Are you passionate about communicating the marvels of chemistry to young people? If so, our PGCE Secondary Chemistry is for you. Your skills and knowledge in chemistry are in demand to inspire young minds and meet the rising demand for GCSE and A Level Chemistry.
Our aim is to help you become a committed, confident and creative teacher so we’ll train you in the essential tools you need to kick-start your career in education. We’ll train you to teach across the years, covering topics from learning how to introduce students to atoms, elements and particles, to thermodynamics and inorganic chemistry. You’ll also learn how to demonstrate impressive chemical reactions safely!
As you progress, you’ll increase your ability to handle the ever-evolving teaching environment, and by the time your course is complete, you’ll be in a positionto continue developing your understanding, knowledge and skills throughout your professional life.
After interview you may be advised you need to take a funded Subject Knowledge Enhancement (SKE) course, which we offer over 16 weeks, before you start your PGCE.
Assignments and school-centred activities are structured around the development of your School Experience Progress Journal (SEPJ) which demonstrates your progress against the nationally agreed competences (the Teachers’ Standards), which all teachers must meet throughout their career. A system of continuous review and assessment of progress in the SEPJ will support your growing ability to take responsibility for your own development.
You must have a good degree (minimum 2:2 but 2:1 or 1st preferred) from a UK higher education institution or equivalent, with a significant chemistry or chemistry-related content, for example from biochemistry or materials science. You must have a GCSE grade C or above (or equivalent) in both English language and mathematics prior to application and if you are offered an interview you will take a written test to assess your standard of English.
For entry onto a teaching course you will also be required to pass the Skills Tests in Literacy and Numeracy. Please visit the Department for Education website for further information.
There is an expectation that you will have had some general experience of working with secondary age students in a school setting. In preparation for the selection interview stage of the recruitment process you are required to engage in a teaching episode, observed by an experienced qualified teacher.
As part of the selection procedure, the interview panel will expect you to demonstrate your knowledge of chemical sciences and will assess personal qualities such as the potential to relate well to secondary age students, enthusiasm, sensitivity, communication skills and robustness and resilience for teaching.
Applicants must also meet The National College for Teaching and Leadership requirements for initial teacher training, which means being medically fit and successfully completing an enhanced disclosure via the Disclosure and Barring Service (DBS).
All applications need to be made via the UCAS Teacher Training website.
Course code: 32XT
The PCCP program aims to integrate Master students within academic and industrial fields of fundamental physical chemistry. Various aspects are concerned: study of matter and its transformations, analysis and control of physical and chemical processes, light-matter interactions and spectroscopy techniques, modelling of physical and chemical processes from molecular to macroscopic scale. Applications cover scientific fields ranging from nanotechnologies, photonics, optoelectronics and organic electronics, to environmental sensors and detection systems.
The PCCP Master is supported by high-level educational and research partners, represented by the consortium of universities engaged in the program. Students follow their courses within a challenging, international environment. Annual summer schools, organized by the consortium partners, complete the students’ training by offering a focus on several topics relative to PCCP.
The first year of the Master degree is focused on the fundamental aspects of Physical Chemistry (thermodynamics, quantum chemistry, spectroscopy and numerical tools). International aspects of the program are introduced progressively during the first year, with some courses taught in English. A remote research project is also programmed to promote collaboration between students of the partner universities within the context of international scientific project management.
The second year is dedicated to specialized topics (advanced spectroscopy and imaging, photonics, computational chemistry, environmental sciences). All courses are taught in English and international mobility is mandatory (at least during the second semester for the Master thesis work), thus strengthening the international dimension of the degree. Numerous mutualized lectures are carried out featuring high-level, local research activity. Practical aspects are emphasized to favor the future integration of the student within the working world.
Master students following the specific UBx-USFQ double degree program spend between five and nine months in Quito (Ecuador) to complete the Master thesis. During this period, assistant professor positions at the USFQ are available for Master students of the program.
Year 1: Courses are in French, except when international students are attending.
Year 2: Courses are in English.
After graduation, students are fully prepared to pursue doctoral studies and a career in research. They may also work as scientists or R&D engineers within the industrial field.
Associated business sectors:
Academic research domains:
Other possible activities:
The cell is the building block of life, the smallest unit with the molecular characteristics of living systems. Increased knowledge of the mechanisms of the biomolecular and biochemical processes in the cell can lead to better medicines, new methods for combating diseases.
The basis of the two-year master’s programme in Life Science and Technology is formed by research carried out in the life sciences and chemistry groups of the Leiden Institute of Chemistry (LIC). Researchers take a science-based approach in finding tailored solutions for complex societal problems as encountered in personalized medicine, systems biology and sustainable use of biological sources. Starting from day one, and during the whole master programme you are a member of a research team in the LIC. Guided by a personal mentor, the student assembles a tailor-made educational programme for optimal training to become a life sciences professional.
Read more about our Life Science and Technology programme.
Find more reasons to study Life Science and Technology at Leiden University.
If you are interested in Life Science and you are looking for a programme with ample of opportunities to assemble your own study path, our Life Science and Technology programme is the right choice. The programme addresses societal problems on a molecular and cellular level. You can also choose a specialisation where you combine one year of Life Science and Technology research with one year of training in business, communication or education.
Read more about the entry requirements for Life Science and Technology.