Chemical Engineering is key in addressing global challenges relating to sustainable supply of clean energy, food and water, through the production of chemicals, functionalised products and fuels. The MSc in Advanced Chemical Engineering provides technical and management training that employers increasingly demand from chemical engineers. The programme offers a general Chemical Engineering option, which covers core chemical engineering subjects and a range of specialised optional modules; and a Biorefining option (formerly the Biofuels Process Engineering MSc), which provides advanced understanding of the production of bioenergy and biofuels while strengthening the knowledge on chemical engineering discipline.
The course is suitable for engineering and applied science graduates who wish to embark on successful careers as chemical engineering professionals.
Our general Chemical Engineering route equips you with diversified skills in advanced engineering, which includes theoretical and practical elements in operation, design, and control of a wide range of chemical processes. The Biorefining route (formerly the Biofuels Process Engineering MSc) equips you with fundamental understanding of chemical engineering and solid skills to address the challenges of the rapidly growing and dynamic bioenergy sector. This option covers the sustainable production of heat, power and fuels from biomass within the biorefining framework. Both routes include training in management applied to the energy sector which enables engineers to effectively fulfil a wider role in a business organisation.
Chemical engineering is a continuously evolving discipline linked to a variety of industries. Chemical engineers lead the design of large-scale facilities in the chemical, petrochemical, and industrial biotechnology sectors.
A distinguished feature of this course is that it is not directed exclusively at chemical engineering graduates. This MSc will provide you with the training and knowledge skill set that employers actively seek in a desirable engineering graduate. We recognise the importance of an interdisciplinary approach; as such the core and optional modules and course contents have been carefully developed to meet the engineering skill shortage currently faced within industry. In particular, no other university in the UK offers a MSc in Advanced Chemical Engineering with a dedicated option in Biorefining. You will develop the professional profile required by the growing biobased sector (more than 480,000 jobs and annual turnover of about €50 million only in the European Union), with a high level of skills' transferability across the chemical and energy sectors.
Cranfield is an exclusively postgraduate university with distinctive expertise in technology and management. There are also numerous benefits associated with undertaking a postgraduate programme of study in here. These include:
The taught programme is delivered from October to February and is comprised of eight modules. The modules are delivered over one week of intensive delivery with the later part of the module being free from structured teaching to allow time for more independent learning and reflection. Students on the part-time programme will complete all of the modules based on a flexible schedule that will be agreed with the Course Director.
The Group Project, undertaken between February and April, enables you to put the skills and knowledge developed during the course modules into practice in an applied context, while gaining transferable skills in project management, teamwork and independent research. Projects are often supported by industry and potential future employers value this experience. The group project is normally multidisciplinary and shared across the Energy MSc programme, giving the added benefit of working with students with other backgrounds.
Each group is given an industrially relevant problem to solve. During the project you will develop a range of skills including learning how to establish team member roles and responsibilities, project management, and delivering technical presentations. At the end of the project, all groups submit a written report and deliver a poster presentation to industry partners. This presentation provides the opportunity to develop presentation skills and effectively handle questions about complex issues in a professional manner.
Part-time students are encouraged to participate in a Group Project as it provides a wealth of learning opportunities. However, an option of an individual dissertation is available if agreed with the Course Director.
The individual research project allows students to investigate deeper into an area of specific interest. It is very common for industrial partners to put forward real world problems or areas of development as potential research project topics. The individual research project component takes place between May and September.
If agreed with the Course Director, part-time students have the opportunity to undertake projects in collaboration with their place of work, which would be supported by academic supervision.
Individual research projects undertaken may involve feasibility assessments, reviews, practical evaluations, designs, simulations, and experimental investigations.
Taught Modules 40%, Group Project 20%, Individual Research Project 40%
Industry driven research makes our graduates some of the most desirable in the world for recruitment by companies competing in a range of industries, including chemicals, petrochemicals, biochemicals, conventional energy and bioenergy, food, materials, consultancy and management.
Those wishing to continue their education via PhD or MBA studies in the chemical or energy sectors will be greatly facilitated by the interdisciplinary, project-oriented profile that they will have acquired through this course.
Process systems engineering deals with the design, operation, optimisation and control of all kinds of chemical, physical, and biological processes through the use of systematic computer-aided approaches. Its major challenges are the development of concepts, methodologies and models for the prediction of performance and for decision-making for an engineered system.
Suitable for engineering and applied science graduates who wish to embark on successful careers as process systems engineering professionals.
The course equips graduates and practising engineers with an in-depth knowledge of the fundamentals of process systems and an excellent competency in the use of state-of-the-art approaches to deal with the major operational and design issues of the modern process industry. The course provides up-to-date technical knowledge and skills required for achieving the best management, design, control and operation of efficient process systems.
Process systems engineering constitutes an interdisciplinary research area within the chemical engineering discipline. It focuses on the use of experimental techniques and systematic computer-aided methodologies for the design, operation, optimisation and control of chemical, physical, and biological processes, e.g. from chemical and petrochemical processes to pharmaceutical and food processes.
A distinguished feature of this course is that it is not directed exclusively at chemical engineering graduates. Throughout the years, the course has evolved from discussions with industrial advisory panels, employers, sponsors and previous students. The content of the study programme is updated regularly to reflect changes arising from technical advances, economic factors and changes in legislation, regulations and standards.
By completing this course, a diligent student will be able to:
This MSc degree is accredited by Institution of Mechanical Engineers (IMechE)
The taught programme for the MSc in Process Systems Engineering is delivered from October to February and is comprised of six compulsory taught modules. There are four optional modules to select the remaining two modules from.
The Group Project, which runs between February and April, enables you to put the skills and knowledge developed during the course modules into practice in an applied context while gaining transferable skills in project management, teamwork and independent research. The group project is usually sponsored by industrial partners who provide particular problems linked to their plant operations. Projects generally require the group to provide a solution to the operational problem. Potential future employers value this experience. This group project is shared across the MSc in Process Systems Engineering and other courses, giving the added benefit of gaining new insights, ways of thinking, experience and skills from students with other backgrounds
During the project you will develop a range of skills including learning how to establish team member roles and responsibilities, project management, and delivering technical presentations. At the end of the project, all groups submit a written report and deliver a presentation to the industrial partner. This presentation provides the opportunity to develop interpersonal and presentation skills within a professional environment.
It is clear that the modern engineer cannot be divorced from the commercial world. In order to provide practice in this matter, a poster presentation will be required from all students. This presentation provides the opportunity to develop presentation skills and effectively handle questions about complex issues in a professional manner.
Part-time students are encouraged to participate in a group project as it provides a wealth of learning opportunities. However, an option of an individual dissertation is available if agreed with the Course Director.
The individual research project allows you to delve deeper into a specific area of interest. As our academic research is so closely related to industry, it is very common for our industrial partners to put forward real-world problems or areas of development as potential research topics.
The individual research project component takes place between April/May and August for full-time students. For part-time students, it is common that their research projects are undertaken in collaboration with their place of work under academic supervision; given the approval of the Course Director.
Individual research projects undertaken may involve designs, computer simulations, feasibility assessments, reviews, practical evaluations and experimental investigations.
Taught modules 40%, Group project 20% (dissertation for part-time students), Individual Research Project 40%
To help students in finding and securing appropriate funding we have created a funding finder where you can search for suitable sources of funding by filtering the results to suit your needs. Visit the funding finder.
This is an advanced, specialist programme in the rapidly expanding area of renewable energy engineering with a clear Mechanical Engineering focus. The programme is aimed at students wishing to develop critical understanding of the significant changes afoot in the energy system due to the development and integration of wind, marine, biomass and solar technologies. The programme will enable graduates to develop and implement creative solutions to the problems encountered in renewable energy capture, conversion, storage and management.
Students will gain the knowledge and skills to assess renewable energy resources, design appropriate renewable energy systems, evaluate the performance of these systems and assess the wider impacts of renewable energy development. The programme provides introductory courses to fundamental energy science and current energy issues, while the project-led courses focus on the design of renewable energy systems. The programme concludes with a research-led dissertation in the summer.
Renewable energy research focuses on six main areas:
Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Power Engineering and Sustainable Energy at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).
The Master's course in Power Engineering and Sustainable Energy places strong emphasis on state-of-the-art semiconductor devices and technologies, advanced power electronics and drives, and advanced power systems. The Power Engineering and Sustainable Energy course also covers conventional and renewable energy generation technologies. Exciting new developments such as wide band gap electronics, energy harvesting, solar cells and biofuels are discussed and recent developments in power electronics are highlighted.
The College of Engineering has an international reputation for electrical and electronics research for energy and advanced semiconductor materials and devices.
Greenhouse gas emission and, consequently, global warming are threatening the global economy and world as we know it. A non-rational use of electrical energy largely contributes to these.
Sustainable energy generation and utilisation is a vital industry in today’s energy thirsty world. Energy generation and conversion, in the most efficient way possible, is the key to reducing carbon emissions. It is an essential element of novel energy power generation system and future transportation systems. The core of an energy conversion system is the power electronics converter which in one hand ensures the maximum power capture from any energy source and on another hand controls the power quality delivered to grid. Therefore the converter parameters such as efficiency, reliability and costs are directly affecting the performance of an energy system.
Transmission and distribution systems will encounter many challenges in the near future. Decentralisation of generation and storage systems has emerged as a promising solution. Consequently, in the near future, a power grid will no longer be a mono-directional energy flow system but a bi-directional one, requiring a much more complex management.
The MSc in Power Engineering and Sustainable Energy is modular in structure. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation. Power Engineering and Sustainable Energy students must successfully complete Part One before being allowed to progress to Part Two.
Part-time Delivery mode
The part-time scheme is a version of the full-time equivalent MSc in Power Engineering and Sustainable Energy scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option.
Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.
Modules on the MSc Power Engineering and Sustainable Energy course can vary each year but you could expect to study:
Advanced Power Electronics and Drives
Power Semiconductor Devices
Advanced Power Systems
Energy and Power Engineering Laboratory
Power Generation Systems
Modern Control Systems
Wide Band-Gap Electronics
Environmental Analysis and Legislation
Communication Skills for Research Engineers
The new home of MSc in Power Engineering and Sustainable Energy is at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.
Engineering at Swansea University has extensive IT facilities and provides extensive software licenses and packages to support teaching. In addition the University provides open access IT resources.
Our new WOLFSON Foundation funded Power Electronics and Power System (PEPS) laboratory well-appointed with the state-of the-art equipment supports student research projects.
Employment in growing renewable energy sector, power electronic and semiconductor sector, electric/hybrid vehicle industry.
The MSc Power Engineering and Sustainable Energy is for graduates who may want to extend their technical knowledge and for professional applicants be provided with fast-track career development. This MSc addresses the skills shortage within the power electronics for renewable energy sector.
BT, Siemens, Plessey, GE Lighting, Schlumberger, Cogsys, Morganite, Newbridge Networks, Alstom, City Technology, BNR Europe, Philips, SWALEC, DERA, BTG, X-Fab, ZETEX Diodes, IQE, IBM, TSMC, IR, Toyota, Hitachi.
As a student on the MSc Power Engineering and Sustainable Energy course, you will learn about numerical simulation techniques and have the opportunity to visit electronics industries with links to Swansea.
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.
With recent academic appointments strengthening electronics research at the College, the Electronic Systems Design Centre (ESDC) has been re-launched to support these activities.
The Centre aims to represent all major electronics research within the College and to promote the Electrical and Electronics Engineering degree.
Best known for its research in ground-breaking Power IC technology, the key technology for more energy efficient electronics, the Centre is also a world leader in semiconductor device modelling, FEM and compact modelling.
This course will provide you with an in-depth specialisation in organic farming and food production systems and it is currently the only specialised MSc in organic and ecological farming in England. You will learn and test the latest approaches in the integrated delivery of soil, crop and livestock, and food supply chain management.
Through a combination of lectures, field trips, seminars, practical classes and research projects you will develop advanced knowledge and skills in:
-Managing organic farming and food production units or businesses in different macroclimatic, agronomic and market contexts
-Agronomic approaches used in organic/biological/ecological/sustainable food production systems
-Underlying principles and standards of organic/biological/ecological/sustainable food production, processing and retailing/marketing systems
-Applied and strategic research underpinning the development of organic and other sustainable farming and food production systems
-A wide range of analytical laboratory methods
You will have the opportunity to attend a 10-day field trip as part of the module on Mediterranean perennial crop production systems in Crete, Greece. The trip is organised in collaboration with ecological farming experts from the Greek National Science Foundation (NAGREF).
As part of your studies you will also undertake a major project, similar to one you might experience in the workplace. You will be supported through training in designing and delivering a laboratory project or field-based investigation. You will collect, analyse and interpret data to produce a thesis reporting your investigation and results in a critical manner.
This research project and thesis may be undertaken at the University, in industry, in Crete as part of existing Nafferton Ecological Farming Group research and development projects, or in another country.
You will benefit from being taught by lecturers who are industry experienced and research active. Our research in integrated agricultural production focuses on soil science, plant science and ecology, spanning a range of scales from: pot – plot – farm – landscape.
Strategic research embraces work on:
Applied research addresses issues of:
-Climate change mitigation (including biofuels)
-Ecological (organic) farming systems
-Low-input crop systems
Professor Carlo Leifert is the Degree Programme Director for MSc in Organic Farming and Food Production Systems. Carlo is a member of the Food Security Network in the Newcastle Institute for Research on Sustainability (NIReS) and is part of the Nafferton Ecological Farming Group (NEFG). He currently manages EU and DEFRA funded projects focused on improving resource efficiency, productivity and food quality and safety in organic and 'low input' crop and livestock production systems.
The course is taught in a block format with a six-week block and then two-week teaching blocks.
You will be taught through:
-Practical and field classes
-Small group discussions
You will be expected to undertake independent study outside of these structured sessions. Your knowledge and understanding will be assessed through written examinations, coursework, presentations and your final major project.
You can also study through the Credit Accumulation Transfer Scheme (CATS). This allows us to award postgraduate level qualifications using credit-bearing stand-alone modules as 'building blocks' towards a qualification. This means that the credits from modules undertaken within a five-year period can be 'banked' towards the award of a qualification.
Our multi-purpose farms provide demonstration facilities for teaching purposes and land-based research facilities (especially in the area of organic production). They are both viable farming businesses.
Cockle Park Farm is a 262ha mixed farm facility that includes the Palace Leas Plots hay meadow experiment and a new anaerobic digestion plant that will generate heat, electricity and digestate - an organic fertiliser - from pig and cattle manure.
Nafferton Farm is a 300ha farm with two main farm units covering conventional and organic farming systems. The two systems are primarily focussed upon dairying and arable cropping.
Both also operate beef production enterprises as a by-product of their dairy enterprises, although the organic system is unique in maintaining a small-scale potato and vegetable production enterprise.
Our modern laboratories provide important teaching and research environments and are equipped with analytical equipment such as High-Performance Liquid Chromatography (HPLCs), GCs, CNS analyser (Carbon and Nitrogen analysis), centrifuges, spectrophotometers and molecular biology equipment. Our specialist research facilities include:
We operate closely with other schools, institutes and the University's central scientific facilities for access to more specialist analytical services.
For work with human subjects we use a purpose built Clinical Research Facility which is situated in the Royal Victoria Infirmary teaching hospital and is managed jointly by us and the Newcastle upon Tyne Hospitals NHS Foundation Trust.
The NU-Food Food and Consumer Research Facility has undergone a £700,000 refurbishment and now boasts a culinary training suite, a sensory laboratory and food handling facility, all supported by multi-functional rooms and a reception.
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.
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 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.
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:
-PhD Degree/Further Studies(Imperial College London, UCL, Cambridge)
-Bioprocess/Biopharma Industry (GSK, Eli Lilley, Synthace)
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.
Visit the Biochemical Engineering Open Days page on the University College London website for more details on opportunities to come and see our facilities and speak to the team!
This programme responds to the rapid growth in the global bioeconomy by providing the core knowledge and skills needed to compete in a rapidly evolving, highly skilled workforce.
The Masters in Management of Bioeconomy, Innovation and Governance (MSc BIG) is an innovative and dynamic postgraduate qualification designed to meet the increasing demand for skilled people in the growing global bioeconomy.
The MSc BIG programme responds to the central challenges of the bioeconomy, including: developing sustainable innovation in a responsible manner; identifying and exploiting value throughout innovation ecosystems; and bringing new technologies to existing and emerging markets.
To meet these modern challenges, MSc BIG provides students with a dynamic set of competencies, and knowledge about life science innovation, as highly desired by prospective employers in the public, private and not-for-profit sectors.
Areas covered by the programme include:
MSc BIG graduates will excel in strategic thinking that brings globally contextualised solutions to practical problems relating to innovation and firm strategy, policy and regulation, collaborative R&D models, and governance and intellectual property.
The MSc BIG programme draws upon real life case studies and the latest research findings from the Innogen Institute. Experiential learning is encouraged, and is accomplished through problem-based group work activities, presentations and interactive seminars, along with conventional lectures.
You will complete five compulsory courses (80 credits) and a selection of optional courses (40 credits), then work on an independently researched dissertation, which can be a conventional academic dissertation or a work-based project.
Basic scientific knowledge is no longer sufficient for building a successful career in the growing bioeconomy. There is a high demand for trained professionals in this area, and this degree is an opportunity to impress prospective employers in the public, private and not-for-profit sectors with expertise in life science innovation.
You may also choose to continue your studies and pursue an academic career in this rapidly growing field.
The transferable skills you gain in areas such as communication and research will give you an edge in the employment market, whatever your eventual career.