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Engineering×

University of Leeds, Full Time MSc Degrees in Engineering

We have 22 University of Leeds, Full Time MSc Degrees in Engineering

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Medical engineering combines the design and problem-solving skills of engineering with medical and biological sciences to contribute to medical device solutions and interventions for a range of diseases and trauma. Read more

Medical engineering combines the design and problem-solving skills of engineering with medical and biological sciences to contribute to medical device solutions and interventions for a range of diseases and trauma.

This exciting and challenging programme will give you a broad knowledge base in this rapidly expanding field, as well as allowing you to specialise through your choice of optional modules.

We emphasise the multidisciplinary nature of medical engineering and the current shift towards the interface between engineering and the life sciences. You could focus on tissue engineering, biomaterials or joint replacement technology among a host of other topics.

Whether you’re an engineer or surgeon, or you work in sales, marketing or regulation, you’ll gain the knowledge and skills to launch or develop your career in this demanding sector.

Institute of Medical and Biological Engineering

You’ll learn in an exciting research environment where breakthroughs are being made in your discipline. This programme is closely linked to our Institute of Medical and Biological Engineering (IMBE), which focuses on research and education in the fields of medical devices and regenerative medicine. It focuses on innovating and translating new therapies into practical clinical applications.

Our world-class facilities in materials screening analysis, joint simulation, surface analysis, heart valve simulation and tensile and fatigue testing allow us to push the boundaries in medical engineering.

Find out more about IMBE

Accreditation

This course is accredited by the Institute of Mechanical Engineers (IMechE) under licence from the UK regulator, the Engineering Council.

Course content

One core module in Semester 1 will give you a background in experimental design and analysis within medical engineering. You’ll look at computational and biological methodologies alongside statistical data analysis and different data visualisation techniques to lay the foundations of your studies.

Optional modules in each semester will allow you to build on this knowledge and focus on specialist topics that suit your own interests and career intentions. You could focus on biomechatronics and medical robotics, spinal biomechanics, surface engineering or computational fluid dynamics analysis and a range of other topics. Depending on your academic or professional background, you may decide to take introductory modules such as Basic Orthopaedic Engineering or Structure and Function of the Body to fill the gaps in your knowledge.

Throughout the programme you’ll complete your Professional Project – an independent piece of research on a topic within mechanical engineering that allows you to demonstrate your knowledge and skills. In the two taught semesters you’ll review the literature around your topic and plan the project, before completing the design, analysis, computation, experimentation and writing up in the summer months.

If you choose to study part-time, you’ll extend your studies over a longer period so you can take fewer modules in each year.

Want to find out more about your modules?

Take a look at the Medical Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Medical Engineering Experimental Design and Analysis 15 credits
  • Professional Project 75 credits

Optional modules

  • Biomaterials and Applications 15 credits
  • Managing for Innovation 15 credits
  • Structure and Function of the Body 15 credits
  • Spinal Biomechanics and Instrumentation (Distance Learning) 15 credits
  • Basic Orthopaedic Engineering 15 credits
  • Surface Engineering 15 credits
  • Biomaterials (Short Course) 15 credits
  • Functional Joint Replacement Technology (Short Course) 15 credits
  • Biomechatronics and Medical Robotics 15 credits
  • Biotribology 15 credits
  • Computational Fluid Dynamics Analysis 15 credits
  • Tissue Engineering 15 credits

For more information on typical modules, read Medical Engineering MSc Full Time in the course catalogue

For more information on typical modules, read Medical Engineering MSc Part Time in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular interactions with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings. Some modules make use of online learning methods or a short course format.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The professional project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects for MSc Medical Engineering students have included:

  • Investigating aspects of wear in total disc replacements
  • Finite element analysis of tissue engineered structures
  • Determining properties of bone and cement augmentation in vertebroplasty
  • Cartilage tribology
  • Investigating 3D printing of a bone substitute

Career opportunities

Career destinations are diverse and include medical engineering within industrial or public sector organisations, regulatory affairs and sales and marketing.

Graduates from this programme have gone on to work in a range of roles for employers such as the clinical research centres, continued in a career in clinical orthopaedics, progressed to a PhD programme.

You’ll also be well prepared to continue with engineering research, whether in industry or at PhD level.

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK's leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website



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This programme will provide you with advanced chemical engineering and process technology skills for exciting and challenging careers in the chemical and process industries. Read more

This programme will provide you with advanced chemical engineering and process technology skills for exciting and challenging careers in the chemical and process industries. This programme also prepares graduates for a PhD study.

If you’ve studied chemical engineering before, you’ll develop your knowledge in key areas such as reaction engineering, process modelling and simulation, pharmaceutical formulation, and fuel processing. If your degree is in chemistry or another related science or engineering discipline, you’ll build your knowledge and skills to convert to a specialisation in chemical engineering.

The course has been designed to provide a greater depth of knowledge in aspects of advanced chemical engineering and a range of up-to-date process technologies. These will enable you to design, operate and manage processes and associated manufacturing plants and to provide leadership in innovation, research and development, and technology transfer.

Specialist facilities

Your Research Project module gives you the chance to study in cutting-edge facilities where our researchers are pushing the boundaries of chemical engineering.

We have world-class facilities for carrying out research in manufacturing (including crystallisation), processing and characterising particulate systems for a wide range of technological materials, as well as facilities for nanotechnology and colloid science/technology.

We also have high performance computing facilities and state-of-the-art computer software, including computational fluid dynamics (CFD), for modelling and simulation of a wide range of processes. This will provide a strong background knowledge in industrial process and equipment design and optimisation.

Accreditation

This course is accredited by the Institution of Chemical Engineers (IChemE) under licence from the UK regulator, the Engineering Council. This adheres to the requirements of further learning for Chartered Engineer (CEng) status.

Course content

The path you take through this programme will depend on your background. If your degree is in Chemical Engineering, you’ll take a suite of compulsory modules on advanced topics such as recent advances in chemical engineering, reaction engineering, multi-scale modelling (including CFD), pharmaceutical formulation and fuel processing. If your degree is not in Chemical Engineering, you’ll build the knowledge you need to succeed in this area with modules such as Separation Processes, Reaction Engineering and Chemical Process Technology and Design.

You’ll then complement this with a choice of optional modules, allowing you to gain specialist knowledge in a topic that suits your career plans or personal interests. Different modules will be available to you depending on your background – for example, if your degree is in Chemical Engineering you could study Process Optimisation and Control, while if your degree is in another subject you might want to gain an understanding of energy management.

Every student undertakes a research project that runs throughout the year. You’ll focus on a topic of your choice that fits within one of the School’s research areas and produce an independent study, reflecting the knowledge and skills you’ve acquired. This will enable you to gain experience of planning, executing and reporting a research work of the type you will undertake in an industrial/academic environment.

Want to find out more about your modules?

Take a look at the Chemical Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Research Project (MSc) 60 credits

Optional modules

  • Team Design Project 15 credits
  • Chemical Products Design and Development 15 credits
  • Separation Processes 30 credits
  • Chemical Process Technology 15 credits
  • Chemical Reaction Processes 15 credits
  • Batch Process Engineering 15 credits
  • Chemical Engineering Principles 15 credits
  • Multi-Scale Modelling and Simulation 30 credits
  • Pharmaceutical Formulation 15 credits
  • Advanced Reaction Engineering 15 credits
  • Nuclear Operations 15 credits
  • Advances in Chemical Engineering 15 credits
  • Fuel Processing 15 credits
  • Materials Structures and Characterisation 15 credits

For more information on typical modules, read Chemical Engineering MSc in the course catalogue

Learning and teaching

We use a variety of teaching and learning methods including lectures, practicals, tutorials and seminars. Independent study is also an important element of the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including problem sheets, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessments.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects by students in MSc Chemical Engineering have included:

  • Control of heat release and temperature levels in jacketed stirred tank vessels
  • Pool boiling heat transfer of nanofluids
  • Effect of surface wettability and spreading on Nanofluid boiling heat transfer
  • Aspen Plus simulation of CO2 removal by amine absorption from power plant
  • Modelling of CO2 absorption using solvents in spray and packed towers
  • Historical data analysis using artificial neural network modelling
  • Computational modelling of particulate flow
  • Characterisation of sedimentation process in two-phase flow based on continuity theory using impedance tomography
  • Finding a new technique for on-line monitoring of crystallisation process using an electrode probe.

A proportion of projects are formally linked to industry, and may include spending time at the collaborator’s site over the summer

Career opportunities

Career prospects are excellent. There is a wide range of career opportunities in the chemical and allied industries in process engineering, process design and research and development as well as in finance and management.

Graduates have gone on to work in a variety of roles at companies like National Environmental Standards and Regulations Enforcement, the National Centre of Science and Technology Evaluation, Invensys Operations Management, Worley Parsons, Hollister-Stier Laboratories, BOC, ASM Technologies and more. 



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This programme offers a broad range of advanced subjects across the mechanical engineering disciplines. It’s aimed at graduate engineers who wish to pursue a career in industry using advanced engineering techniques, or those who want to gain in-depth knowledge for a career in research in industry or academia. Read more

This programme offers a broad range of advanced subjects across the mechanical engineering disciplines. It’s aimed at graduate engineers who wish to pursue a career in industry using advanced engineering techniques, or those who want to gain in-depth knowledge for a career in research in industry or academia.

We emphasise the application of computational methods and packages in mechanical engineering analysis design and manufacture to solve complex engineering problems, but you’ll choose from a wide variety of options that allow you to tailor your studies to suit your own interests or career ambitions. You could gain specialist knowledge in mechatronics and robotics, automotive engineering, tribology, aerospace engineering and many more.

You’ll be taught in world-class facilities by researchers who are making breakthroughs in their fields. It’s an excellent opportunity to gain a wide range of knowledge and skills that will prepare you for an exciting and challenging career.

Specialist facilities

We have an impressive range of world-class facilities to support your studies. In addition to our advanced CAD facilities for design work, we have the latest industry-standard software for computational fluid dynamics and finite element modelling of material stress analysis.

There’s also a well-equipped workshop with CNC machinery, 3D printing facilities and wire EDM for building parts and extensive lab facilities for solid and fluid dynamics, erosion, corrosion, tribology, combustion, control and dynamics, robotics and optical measurement.

Accreditation

This course is accredited by the Institute of Mechanical Engineers (IMechE) under licence from the UK regulator, the Engineering Council

Course content

In Semester 1 you’ll take a core module that introduces you to the fundamentals of computational and experimental methods, laying the groundwork for the rest of your studies. Beyond this, you’ll be able to choose modules in areas that suit your interests and career aspirations such as Combustion in Engines, fluid dynamics analysis, biomaterials or aspects of automotive and aerospace engineering.

Throughout the programme you’ll complete your Professional Project – an independent piece of research on a topic within mechanical engineering that allows you to demonstrate your knowledge and skills. In the two taught semesters you’ll review the literature around your topic and plan the project, before completing the design, analysis, computation, experimentation and writing up in the summer months.

If you choose to study part-time, you’ll extend your studies over a longer period so you can take fewer modules in each year.

Want to find out more about your modules?

Take a look at the Advanced Mechanical Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Engineering Computational Methods 15 credits
  • Professional Project 75 credits

Optional modules

  • Finite Element Methods of Analysis 20 credits
  • Mechatronics and Robotics Applications 15 credits
  • Automotive Chassis Engineering 15 credits
  • Automotive Driveline Engineering 15 credits
  • Energy Systems, Policy and Economics for Engineers 15 credits
  • Surface Engineering 15 credits
  • Biomaterials (Short Course) 15 credits
  • Functional Joint Replacement Technology (Short Course) 15 credits
  • Introduction to Tribology 15 credits
  • Aerospace Structures 15 credits
  • Rotary Wing Aircraft 15 credits
  • Vehicle and Product Systems Design 15 credits
  • Computational Fluid Dynamics Analysis 15 credits

For more information on typical modules, read Advanced Mechanical Engineering MSc(Eng) Full Time in the course catalogue

For more information on typical modules, read Advanced Mechanical Engineering MSc(Eng) Part Time in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Career opportunities

After graduating from this course, you will be in a good position to seek employment with many leading organisations such as Airbus, Bentley Motors, Bombardier Transportation, Crompton Technology Group, Cummins UK, DePuy International, EAS Engineering, E-ON UK, Faraday Packaging Partnership, Ford Motor Company, Jaguar Land Rover, Nissan Motor Company, Prodrive, Ricardo UK and Siemens.

Careers support

You’ll have access to the wide range of engineering andcomputing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK’s leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



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Structural engineers help to make, shape and maintain the built environment, from buildings and bridges to water supply systems, power plans and flood defences. Read more

Structural engineers help to make, shape and maintain the built environment, from buildings and bridges to water supply systems, power plans and flood defences. They are professionals who enjoy innovation, challenges, opportunities, responsibility and excitement in a varied and very satisfying career. As a profession, structural engineering provides a tremendous opportunity to make a real difference to peoples' lives and their environment.

This programme will equip you with the advanced knowledge and skills to succeed in this challenging industry. You’ll build your knowledge of a range of core topics such as concrete and steel design, structural analysis, design optimisation and how structures are designed and managed in earthquake zones. You’ll also develop your research skills and focus on a specific topic when you complete your own research project.

Taught by leading academics and practitioners, you’ll prepare to face some of the major challenges of the 21st century.

This programme has close links with local and regional industry as well as the Yorkshire branch of the Institution of Structural Engineers (IStructE) – and you’ll benefit from the expertise of our Institute for Resilient Infrastructure and the active research groups across the Faculty of Engineering.

You’ll also benefit from using our specialist facilities, such as bench-top testing facilities to look at the fundamental behaviour of material soils and testing rigs for full-scale structures. We have all the specialist software you’ll need for your programme, and you’ll have access to a dedicated study suite for Masters students.

Accreditation

This degree is accredited by the Joint Board of Moderators as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired a partial CEng accredited undergraduate first degree.

This course is also accredited by EUR-ACE, the European quality label for engineering degree programmes at Bachelor and Master level.

Course content

You’ll study a set of core modules that give you a firm foundation in the key elements of structural engineering. You’ll develop and expand your understanding of structural analysis and foundation engineering, and explore design issues related to key building materials like concrete, steel and composites. From there you’ll explore design optimisation and examine real-life examples.

We place a strong emphasis on applying your knowledge to real-world problems. Over the 2 semesters, you’ll work on your own design project, where you’ll develop, evaluate and recommend concept design solutions to a structural engineering problem and even put together an outline construction programme for the project.

During Semester 1 and 2 but particularly over the summer months, you’ll also develop and apply your research skills to a real-world problem when you complete an independent research project.

Want to find out more about your modules?

Take a look at the Structural Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Design and Management of Structures in Earthquake Zones 15 credits
  • Advanced Structural Analysis (MSc/PGD) 15 credits
  • Design Optimisation - MSc 15 credits
  • Advanced Concrete Design (MSc) 15 credits
  • Structural Engineering Dissertation 60 credits
  • Foundation Engineering (MSc) 15 credits
  • Advanced Steel and Composite Design - (MSc) 15 credits
  • Structural Engineering Design Project 30 credits

For more information on typical modules, read Structural Engineering MSc(Eng) Full Time in the course catalogue

For more information on typical modules, read Structural Engineering MSc(Eng) Part Time in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The dissertation project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects by MSc Structural Engineering students have included:

  • Dynamic shear resistance of collar jainted masonry panels
  • Performance of reinforced concrete tunnel linings in fire situations
  • A comparison of tensile and compressive creep in concrete
  • Review of the latest developments in the design and construction of plastic bridges

A proportion of projects are formally linked to industry, and can include spending time at the collaborator’s site over the summer.

Career opportunities

This programme greatly enhances your ability to obtain status as a Chartered Structural Engineer. As a result, you may expect to find employment in the major structural engineering consulting practices, while opportunities also exist with multidisciplinary consulting organisations.

Graduates have gone on to succeed in a range of careers around the world for organisations sucj as Arup, Delf Consulting Engineers (India), G2 Structural Ltd, JN Bentley Ltd, KA Tech Tips Ltd, SkyCon Design & Construction Co. Ltd and Sterling Engineering Consultancy Services among others.

If you are taking the course on a part-time basis, you will return to your existing jobs with enhanced potential for progression.

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK’s leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



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This programme will equip you with the knowledge and skills you need to meet the needs of the automotive industry in the advanced areas of analysis, design and manufacture. Read more

This programme will equip you with the knowledge and skills you need to meet the needs of the automotive industry in the advanced areas of analysis, design and manufacture.

Traditionally, the sector has been associated with high-volume vehicle manufacture, but the past decade has seen the landscape shift towards automotive component manufacturers and specialist design and consultancy house.

This course will prepare you to work in a range of different settings. Core modules will develop your knowledge of key fields such as chassis and driveline engineering, as well as vehicle and product systems design. You’ll then choose from optional modules on topics that suit your own interests and career intentions.

We put particular emphasis on computational methods and software packages in automotive engineering analysis, design and manufacture. Depending on the modules you choose, you could use Matlab, Abaqus finite element code, Fluent CFD, SolidWorks CAE and LabView (DAQ and control).

Specialist facilities

You’ll benefit from working in world-class specialist facilities for different aspects of automotive engineering. These include a brake test area and measurement lab, as well as the latest industry-standard software for computational fluid dynamics and finite element modelling of systems and materials. ADAMS software is also available for suspension simulation.

High-level CNC and wire EDM facilities are available in the Faculty workshop, and we have cutting-edge tribology facilities to study wear on engine parts. There’s even a ‘stirred bomb’ for characterising fuel ignition and advanced engines with optical access. If you get involved with Formula Student race car, you’ll also use our dedicated car build area including computerised engine test bays.

This programme is also available to study part-time over 24 months.

Accreditation

This course is accredited by the Institute of Mechanical Engineers (IMechE) under licence from the UK regulator, the Engineering Council.

Course content

Core modules will give you a solid knowledge base in key areas of automotive engineering. You’ll build your understanding of how vehicle and product systems are designed and developed, as well as automotive driveline and chassis engineering.

This foundation will allow you to gain specialist knowledge in areas that particularly interest you when you choose from our range of optional modules. You could focus on topics such as computational methods, tribology, combustion in engines or applications of mechatronics among many others.

Throughout the programme you’ll complete your Professional Project – an independent piece of research on a topic within mechanical engineering that allows you to demonstrate your knowledge and skills.

In the two taught semesters you’ll review the literature around your topic and plan the project, before completing the design, analysis, computation, experimentation and writing up in the summer months. You could even get involved with the Formula Student race car through your project.

If you choose to study part-time, you’ll extend your studies over a longer period so you can take fewer modules in each year.

Want to find out more about your modules?

Take a look at the Automotive Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Automotive Chassis Engineering 15 credits
  • Automotive Driveline Engineering 15 credits
  • Vehicle and Product Systems Design 15 credits
  • Professional Project 75 credits

Optional modules

  • Vehicle Design and Analysis 20 credits
  • Mechatronics and Robotics Applications 15 credits
  • Engineering Computational Methods 15 credits
  • Surface Engineering 15 credits
  • Introduction to Tribology 15 credits
  • Computational Fluid Dynamics Analysis 15 credits

For more information on typical modules, read Automotive Engineering MSc(Eng) Full Time in the course catalogue

For more information on typical modules, read Automotive Engineering MSc(Eng) Part Time in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The professional project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects for MSc Automotive Engineering students have included:

  • Regenerative braking systems – Impact on fuel consumption and vehicle stability in HEVs
  • Thermo-mechanical analysis of disc brake for vehicle rollaway
  • Coated lightweight brake rotors
  • Designing, Measuring and Modelling of Vehicle Dynamics

A proportion of projects are formally linked to industry, and can include spending time at the collaborator’s site over the summer. You can also get involved with projects linked to the design, construction and testing of the Formula Student race car.

Career opportunities

Career prospects are excellent and with this qualification you should expect to find employment in the automotive and motor sport industries.

Graduates from this programme are working for employers such as Bentley Motors, BMW UK, Jaguar Land Rover, Honda, Nissan Motor Company, Renault F1 (Lotus Renault GP), Red Bull Racing and Ricardo UK.

Alternatively, you may choose to work in the general engineering industry, undertake PhD study or move into a completely different field such as finance or teaching.




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This course will provide you with an in-depth knowledge of how to deliver effective modern water supply, sanitation and other public health interventions in urban and rural areas in low-income and transitional economies. Read more

This course will provide you with an in-depth knowledge of how to deliver effective modern water supply, sanitation and other public health interventions in urban and rural areas in low-income and transitional economies.

Aimed at consultants, and working professionals in national and local government, non-government organisations, international development organisations and public health agencies, it has a strong focus on developing practical and policy skills and addresses the critical future challenges of climate change, population growth and urbanisation. You’ll develop your understanding of technical interventions in water supply, sanitation and solid waste management.

Run in conjunction with the Nuffield Centre for International Health and Development, one of the UK’s preeminent public health research centres, and informed by research undertaken by our Institute for Public Health and Environmental Engineering, this programme will give you the knowledge and skills to identify and deliver investments that will have major benefits for health and development.

Institute for Public Health and Environmental Engineering

Our Institute for Public Health and Environmental Engineering is renowned worldwide for its pioneering work in developing countries. The institute undertakes research in all aspects of the built environment in which the presence of pathogens influences design, including water treatment, solid waste and airborne transmission of disease.

Staff teaching on this course have close working links with a number of key institutions in the field of international development, including UNICEF, the World Bank, the World Health Organization, the Water Supply and Sanitation Collaborative Council, WaterAid, World Vision, the Bill and Melinda Gates Foundation and the African Development Bank.

You’ll also benefit from using our specialist facilities, such as our public health labs with separate areas for solid waste, water and wastewater, and a class II microbiology lab and clean room. We have all the specialist software you’ll need for your programme, and you’ll have access to a dedicated study suite for Masters students.

Accreditation

This degree is accredited by the Joint Board of Moderators as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired a partial CEng accredited undergraduate first degree.

This course is also accredited by EUR-ACE, the European quality label for engineering degree programmes at Bachelor and Master level.

Course content

A series of compulsory modules will develop your knowledge and skills in a range of areas. You’ll gain an understanding of the wider issues surrounding public health around the world and how they impact on policy and practice, as well as current debates around the complex topics of health, equity and development understand how health policy is shaped and planned.

At the same time, you’ll be introduced to the principles and practice of public health engineering to bridge the gap between theory, policy and practice and explore key technologies in water supply, sanitation, wastewater and solid waste management. You’ll also consider engineering responses to complex emergencies, especially regarding the provision of water supply, sanitary services and shelter.

You’ll build your knowledge of technical issues in water resource and sold waste management, as well as natural wastewater treatment, and undertake an independent research project. Working with your supervisor, you’ll complete this research or design-based project during the summer months at the end of the programme to demonstrate the knowledge and skills you’ve gained.

Want to find out more about your modules?

Take a look at the 2016 Water, Sanitation and Health Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • The Management of WASH Projects 15 credits
  • Engineering for Public Health 15 credits
  • Wastewater and Fecal Sludge Management 15 credits
  • Water Resource Management 15 credits
  • Water Supply 15 credits
  • Solid Waste Management 15 credits
  • Water, Sanitation and Health Engineering Dissertation 60 credits
  • Engineering in Emergencies - MSc 15 credits
  • Key Issues in International Health 15 credits

For more information on typical modules, read Water, Sanitation and Health Engineering MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Career opportunities

This programme will equip you with a unique blend of civil engineering and public health policy skills.

As a result, you’ll be ideally placed to take up a senior position in public health ministries and public health departments in countries of the global south, or to work with international development agencies and international non-governmental organisations (NGOs).

Graduates have gone on to work for organisations such as WaterAid Liberia/Sierra Leone, Greater Manchester Waste Disposal Authority and the Center for Disease Control and Prevention.

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK’s leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



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One of the fundamental challenges associated with hydrocarbon production is ensuring the integrity of the assets used to extract and transport process fluids, particularly from effects such as internal corrosion. Read more

One of the fundamental challenges associated with hydrocarbon production is ensuring the integrity of the assets used to extract and transport process fluids, particularly from effects such as internal corrosion. As a result, the demand for qualified corrosion engineers with specific expertise in oilfield operations continues to grow.

This course is appropriate for professional engineers in industry who are seeking to expand their expertise, as well as graduate engineers or physical scientists looking to gain specialist knowledge relevant to the oil and gas sector.

The course develops your skills in measuring, predicting and managing corrosion as well as assessing asset integrity. Optional modules allow you to focus on topics relevant to your interests and career plans.

Taught by academic staff at the forefront of their fields, the course enables you to develop a range of skills and a solid knowledge base from which to launch an exciting career within the oil and gas industry.

You’ll learn in a stimulating research environment supported by world-class specialist facilities which support the individual project element of the programme. These include access to equipment such as high temperature/high pressure autoclaves, quartz crystal microbalance, erosion-corrosion rigs/flow loops, rotating cylinder electrodes/bubble cells, visualisation cells and potentiostats with AC/DC capabilities.

The projects are also supported by access to our corrosion lab’s own advanced surface analysis suite, containing optical microscopes, mini-sims, IR/UV spectroscopy techniques, atomic force microscopes and a nano-indenter.

Accreditation

This course is accredited by the Institute of Mechanical Engineers (IMechE) under licence from the UK regulator, the Engineering Council.

Course content

Core modules in each semester provide you with a thorough understanding of key aspects of oilfield corrosion engineering. You’ll study topics which cover aspects such as material selection, chemical inhibition, surface engineering technologies, the principles of physical metallurgy, electrochemistry and corrosion management strategies for new or mature assets.

You’ll also select from optional modules that allow you to focus on specific topic areas such as tribology and its impact on mechanism design or engineering computation. Modules are also available through Leeds University Business School covering aspects of operations management, to prepare you for a range of roles in industry.

Throughout the programme you’ll complete your Professional Project – an independent piece of research on a topic within mechanical engineering that allows you to demonstrate your knowledge and skills. In the two taught semesters you’ll review the literature around a specific topic (chosen from an extensive list provided) and plan the project, before completing the design, analysis, computation, experimentation and writing up in the summer months.

Want to find out more information about your modules?

Take a look at the Oilfield Corrosion Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Metals and Alloys 15 credits
  • Materials Selection and Failure Analysis 15 credits
  • Oilfield Chemistry and Corrosion 15 credits
  • Advanced Oilfield Corrosion 15 credits
  • Surface Engineering 15 credits
  • Professional Project 75 credits

Optional modules

  • Materials Structures and Characterisation 15 credits
  • Risk Perception and Communication 15 credits
  • Effective Decision Making 15 credits
  • Managing for Innovation 15 credits
  • Engineering Computational Methods 15 credits
  • Introduction to Tribology 15 credits
  • Computational Fluid Dynamics Analysis 15 credits

For more information on typical modules, read Oilfield Corrosion Engineering MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, poster sessions, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The professional project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Most projects are experimentally based and linked with companies within the oil and gas industry to ensure the topic of research is relevant to the field whilst also addressing a real-world problem.

Recent projects for MSc Oilfield Corrosion Engineering students have included:

  • Corrosion of wellbore materials under high temperature and pressure
  • Nanotechnology applications in oil and gas for advanced corrosion protection
  • Evaluation of green inhibitors
  • Understanding galvanic corrosion of welds in high shear conditions
  • Application of acoustic emission as a tool for predicting erosion severity
  • Development and testing of a novel, custom cell to understand top of line corrosion

Career opportunities

With this qualification, excellent career options are open to you to practise as a professional corrosion engineer and play a major role in ensuring the safe and efficient recovery of natural resources.

Graduates have gone on for a range of companies such as BP, Petronas, Wood Group Kenny and EM&I.

You’ll also be well prepared to continue with research in this field, either within industry or at PhD level within academia.

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UKs leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website



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This programme will provide you with the advanced knowledge and skills to pursue a successful career in the oil and gas industry. Read more

This programme will provide you with the advanced knowledge and skills to pursue a successful career in the oil and gas industry.

You’ll study modules covering core topics related to the downstream activities of the industry including drilling and production technology, oilfield chemistry and corrosion, and chemical reaction processes. You’ll also have the option to take modules in topics such as separation processes, process optimisation and control, and multi-scale modelling and simulation.

Practical work supports your lectures and seminars, as you split your time between the lab and the classroom. You’ll also undertake a major research project investigating a specific topic in petroleum production engineering, which could relate to your own interests or career intentions. Taught by experts in our world-class facilities, you’ll gain the knowledge and skills to thrive in a challenging and exciting industry.You’ll benefit from the chance to study in cutting-edge facilities where our researchers are pushing the boundaries of chemical and process engineering. We have facilities for characterising particulate systems for a wide range of technological materials, as well as facilities for fuel characterisation, environmental monitoring and pollution control. In our Energy Building, you’ll find an engine testing fuel evaluation and transport emissions suite and other characterisation equipment.

Accreditation

We are seeking accreditation from the Energy Institute.

Course content

Most of the course revolves around core modules, giving you a range of knowledge relating to different aspects of downstream petroleum production processes. These will include chemical reaction processes, drilling and production technologies and oilfield chemistry and corrosion.

You’ll look at the principles of process performance analysis, refining theory, enhanced oil recovery, chemicals used in corrosion control and strategies for new or mature assets. On top of this, you’ll take an optional module that allows you to develop your knowledge in an area that suits your own interests.

In the summer months you’ll undertake a research project, which will demonstrate the skills you’ve gained and may even be linked to your future career plans.

Want to find out more about your modules?

Take a look at the Petroleum Production Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Research Project (MSc) 60 credits
  • Chemical Reaction Processes 15 credits
  • Fuel Processing 15 credits
  • Advanced Drilling and Production Technology 15 credits
  • Drilling and Production Technology 30 credits
  • Unconventional Oil and Gas Reservoirs 15 credits

Optional modules

  • Separation Processes 30 credits
  • Multi-Scale Modelling and Simulation 30 credits
  • Rock Mechanics 15 credits
  • Petroleum Reservoir Engineering 15 credits

For more information on typical modules, read Petroleum Production Engineering MSc in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings. Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Examples of project topics would include:

  • Enhancement of mechanical strength and corrosion inhibition in oil pipelines
  • Reducing oil pipeline scaling using nano-particle seeding agents
  • Monitoring pipeline flows using electrical resistance tomography (ERT)
  • The application of nano-technology in enhancing oil recovery
  • Application of polymer-based nano-particles in absorbing and controlling oil spillages
  • Tribo-electrostatic beneficiation of oil shale using a powder dispersal system

A proportion of research projects are formally linked to industry, and can include spending time at the collaborator’s site over the summer.

Career opportunities

The programme’s main focus is on downstream petroleum industry activities such as drilling, production, refining and distribution.

With an MSc degree in Petroleum Production Engineering you could expect to pursue a successful career in the oil and gas industries in a wide range of areas as diverse as field engineering, production drilling engineering, pipeline and transportation logistics, refinery operations and management, refinery control and optimisation, and sales and marketing.

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK’s leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



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

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

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

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

Specialist facilities

You’ll benefit from the chance to study in cutting-edge facilities where our researchers are pushing the boundaries of materials science and engineering and metallurgy. We have state-of-the-art preparative facilities for making and characterising a wide range of materials, as well as equipment and instrumentation for carrying out more fundamental studies into their process-microstructure-property relationships.

Accreditation

The course is designed to provide graduates with the educational base required for Chartered Engineer (CEng) status. Accreditation is currently being sought from IoM3

Course content

Compulsory modules at the beginning of the programme lay the foundations of your studies in materials science or metallurgy. You’ll learn about processing-structure-property relationships, which lie at the heart of the discipline, as well as examining topics such as mechanical, physical and chemical behaviour, phase transformations and how the structure and local chemistry of materials may be characterised. You’ll cover materials and process selection and their role in design, and extend this into the principles and practice of failure analysis.

This prepares the way for three sets of specialist modules: you can decide to specialise in metallurgy, functional and nanomaterials or take a broader materials science approach covering metals, ceramics, polymers, composites and biomaterials. You’ll complete your taught modules either by studying a module in materials modelling (if you already hold an accredited Engineering degree) or participating in an industry-focused interdisciplinary design project.

You will complete your programme with a major individual research project of your own. With guidance from your supervisor, you will work on a topic related to the internationally-leading materials and metallurgical research carried out in the University, or you could propose a topic of your own related to your own professional work or that of an industrial sponsor.

Want to find out more about your modules?

Take a look at the Materials Science and Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Research Project (MSc) 60 credits
  • Phase Transformations and Microstructural Control 15 credits
  • Structure-Property Relationships 15 credits
  • Materials Selection and Failure Analysis 15 credits
  • Materials Structures and Characterisation 15 credits

Optional modules

  • Team Design Project 15 credits
  • Biomaterials and Applications 15 credits
  • Materials Modelling 15 credits
  • Materials for Functional Applications 30 credits
  • Metals and Alloys 15 credits
  • Ceramics, Polymers and Composites 15 credits
  • Nanomaterials 15 credits
  • Process Metallurgy 15 credits
  • Extractive Metallurgy 15 credits

For more information on typical modules, read Materials Science and Engineering MSc in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of the discipline through lectures, seminars, tutorials, small group work and project meetings. Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments, vivas and projects.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects by MSc Materials Science and Engineering students have included:

  • Hydrothermal synthesis of metal oxide nanoparticles
  • Temperature variable X-ray diffraction of high temperature piezoelectric material BiFeO3-KBiTiO3-PbTiO3
  • Fabrication of glass waveguide devices by femtosecond laser inscription
  • Microstructure development in drop-tube processed cast iron
  • Validation of cooling rate models of drop-tube processing
  • Characterisation of graphite nanoplatelets (GNPs) produced by solvent exfoliation of graphite
  • Studies of the effect of milling variables in the production of nanoparticles
  • Microstructural investigation of spray atomized powders

Career opportunities

There is currently an increasingly high demand for qualified materials scientists, materials engineers and metallurgists.

Career prospects are excellent and cover a wide range of industries concerned with the research and development of new and improved materials, materials synthesis and commercial production, and materials exploitation in cutting-edge applications in engineering and technology.

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UKs leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



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In just a brief duration of time - in a few minutes or even in a fraction of a second - a fire or an explosion can have catastrophic consequences in residential buildings or in industrial plant. Read more

In just a brief duration of time - in a few minutes or even in a fraction of a second - a fire or an explosion can have catastrophic consequences in residential buildings or in industrial plant. In UK alone, hundreds get killed and tens of thousands are injured every year. Some single incidents cost millions of pounds, the total monetary cost of fire and explosions in the UK is estimated at £12 billion per year or approximately 1% of GDP.This course offers students from diverse academic backgrounds advanced training in the field of Fire and Explosion Engineering for those wishing to embark on a career, or further develop their career, in the industry. Particular emphasis is placed on fire and explosion protection systems within a legislative framework that is complex and fast-changing.Core modules will cover both foundation and advanced aspects of fire and explosion engineering, from the factors that influence flame spread to the latest research in explosion prediction. You’ll also gain a firm grounding in fire safety design and have the chance to design a fire protection system for a complex building.

Specialist facilities

  • An Enclosed Fire Rig Test facility
  • The Cone Calorimeter (standard and modified with controlled ventilation)
  • A 1m³ indicative standard fire furnace (planned for 2017)
  • Purser furnace
  • The Limiting Oxygen Index apparatus
  • The standard ISO vessel for dust explosions (in storage until at least 2017)
  • TGA (trace gas analyzer) and GC (gas chromatography) analytical equipment (off-line).
  • The on-line FTIR (Fourier transform infrared) toxic product analysis.
  • Mass spectrometer (MS).
  • Particulate emissions measurements (including particle size)
  • Access to the world class Leeds Electron Microscopy and Spectroscopy Centre (LEMAS), within the School, and high speed photography for visualisation of fast processes and optical analysis of particles before and after reaction.

Some of the modules on this programme are offered as short courses by the Faculty of Engineering’s Continuing Professional Development unit.

Find out more about our Fire Engineering short courses

This programme is also available to study part-time over 36 months.

Course content

You’ll study core modules that allow you to understand issues such as flame spread and steady burning, as well as developing your knowledge of fire protection designs for complex buildings. You’ll also review research around explosions, how they can be predicted and mitigated.

A major part of the MSc are two projects that will give you valuable experience and skills.

The first project involves the design of a protection system, so you’ll learn about the application of techniques such as sprinklers, pressurisation, smoke venting, automatic fire detectors, means of escape and emergency lighting systems.

The other is a lab or computational based project taking into account your own preferences. You can choose from the list of topics we offer each year, but most part-time students choose to put forward their own topic which may be related to the interests of the employer or sponsor. If you take this course part-time with the support of your employer, you can undertake your projects in the workplace.

Both projects are assessed on the basis of a written dissertation and an oral presentation.

If you choose to study part-time, you’ll need to visit Leeds six or seven times over three years. You’ll attend two presentation days and either four or five teaching weeks, depending on whether you choose the e-learning module Fire Risk Assessment and Management.

Course features include:

  • Extensive participation in course delivery by lecturers from industry brings strong industrial involvement to the course
  • Most taught modules are delivered in intensive CPD one week format. Modules are spread evenly throughout the year
  • Extensive participation in course delivery by lecturers from industry brings strong industrial involvement to the training package
  • Projects can be undertaken in the workplace (part-time) or at the University (full time and part time)
  • Block module format allows both full-time and part-time students a choice of modules.

The taught modules are assessed by coursework and 'open book' tests; typically within a period of 6-10 weeks from start to finish.

Want to find out more about your modules?

Take a look at the Fire and Explosion module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Research Project (MSc) 60 credits
  • Fire Safety Design 45 credits
  • Fire Risk Assessment and Management 15 credits
  • Fire Dynamics and Modelling 15 credits
  • Fire and Explosion Investigation 15 credits
  • Explosion Prediction and Mitigation 30 credits

For more information on typical modules, read Fire and Explosion Engineering MSc Full Time in the course catalogue

For more information on typical modules, read Fire and Explosion Engineering MSc Part Time in the course catalogue

Learning and teaching

Each taught module is delivered in an intensive one-week block, allowing full and part-time students to study alongside each other. These teaching weeks will allow you to benefit from the expertise of our own academics – informed by their groundbreaking research – as well as a range of visiting lecturers from industry to gain an understanding of fire and explosion engineering in theory and practice.

Assessment

Taught modules are assessed by via coursework and ‘open book’ tests, typically within 6-10 weeks from start to finish.

Career opportunities

Challenging career opportunities for fire and explosion professionals are available in just about every type of business, industry and government operation.

They include fire and explosion consultancies, fire safety planning offices of local authorities, civil engineering and architectural companies, chemical/pharmaceutical companies, the oil and gas industries, fire and explosion protection equipment manufacturers, government bodies and departments, specialist research and testing labs and insurance companies.

Links with industry

Throughout the course you will have the opportunity to meet potential employers at the week-long taught courses.

The Fire programme at Leeds is actively supported and sponsored by, amongst others, the following companies/organisations:




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The huge growth of processing power, now available in small power-efficient packages, has fuelled the digital revolution, which has touched all sectors of the economy. Read more

The huge growth of processing power, now available in small power-efficient packages, has fuelled the digital revolution, which has touched all sectors of the economy. This practically orientated, advanced course in the area of electronics design and applications provides a strong digital technology core backed with applications-led modules.

You’ll study applications as diverse as medical and electronics, e-health, intelligent building design, automotive electronics, retail and commerce to prepare you for a range of careers in industry, where the skills you gain will be in high demand. A substantial element of practical work will give you confidence with software and digital hardware implementations using microcontrollers, FPGA, DSP devices and general system-on-chip methodology.

You’ll be taught by experts informed by their own world-leading research, and you’ll have access to world-class facilities to prepare for a career in a fast-changing industry.

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities . These include our Keysight Technologies wireless communications lab, as well as labs for embedded systems, power electronics and drives, ultrasound and bioelectronics.

There’s also a Terahertz photonics lab, class 100 semiconductor cleanroom, traffic generators and analysers, FPGA development tools, sensor network test beds. We have facilities for electron-beam lithography and ceramic circuit fabrication – and a III-V semiconductor molecular beam epitaxy facility.

Accreditation

This course is accredited by the Institution of Engineering and Technology (IET) under licence from the UK regulator, the Engineering Council.

Course content

The programme is built around a set of core modules that will develop your knowledge and skills areas such as digital signal processing, embedded microprocessor systems and how electronics and communications technology could be used in healthcare. You’ll also take a core lab-based module to give you experience of different circuits, systems, equipment and tools.

Optional modules will give you the chance to develop specialist knowledge. If you don’t have any experience of C programming, you’ll take Programming – otherwise, you can choose to take either this module of Software Development. Then you’ll choose one additional module specialising either in data communications and network security or the principles of digital wireless communications.

To build your understanding of the global electronics industry, you’ll also complete a dissertation. This could take the form of a business, manufacturing or outsourcing plan, a proposal for research funding or an essay on a specific aspect of the industry.

Over the summer months you’ll also work on your research project. This gives you the chance to work as an integral part of one of our active research groups, focusing on a specialist topic in computer science and selecting the appropriate research methods.

Want to find out more about your modules?

Take a look at the Embedded Systems Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Digital Signal Processing for Communications 15 credits
  • Mini Projects and Laboratory 15 credits
  • FPGA Design for System-on-Chip 15 credits
  • Digital Media Engineering 15 credits
  • Embedded Microprocessor System Design 15 credits
  • Medical Electronics and E-Health 15 credits
  • Main Project 45 credits

Optional modules

  • Digital Wireless Communications Principles 15 credits
  • Data Communications and Network Security 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Embedded Systems Engineering MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

A proportion of projects are formally linked to industry, and may include spending time at the collaborator’s site over the summer.

Career opportunities

Embedded systems are ubiquitous in engineering and graduates are likely to find employment in a wide and diverse range of industries including: communications, automotive, transport, construction, industrial, automation, energy and environmental monitoring

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK’s leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website



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Commercial products today combine many technologies, and industry is increasingly interdisciplinary. This course is designed to meet this demand, giving you an interdisciplinary knowledge base in modern electronics including power, communications, control and embedded processors. Read more

Commercial products today combine many technologies, and industry is increasingly interdisciplinary. This course is designed to meet this demand, giving you an interdisciplinary knowledge base in modern electronics including power, communications, control and embedded processors.

You’ll develop a broad grasp of a range of interlocking disciplines, combining core modules developing your practical lab skills and industry awareness with a range of optional modules that allow you to focus on topics that suit your interests or career plans. Next-generation silicon technologies, electric drives and generating electric power from renewable sources are among the topics you could study.

This course will appeal to people with a broad interest in electronics and communications, as well as those who are interested in modern communications techniques, radio propagation, cellular mobile systems, control systems, power and drives, and modern system on-chip technology.

Specialist facilities

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities. These include our Keysight Technologies wireless communications lab, as well as labs for embedded systems, power electronics and drives.

Depending on your choice of project, you may have use of our Terahertz photonics lab, ultrasound and bioelectronics labs, class 100 semiconductor cleanroom, traffic generators and analysers, FPGA development tools, sensor network test beds.

The School also contains facilities for electron-beam lithography and ceramic circuit fabrication – and a III-V semiconductor molecular beam epitaxy facility. The Faculty is also home to the £4.3 million EPSRC National Facility for Innovative Robotic Systems, set to make us a world leader in robot design and construction.

Accreditation

This course is accredited by the Institution of Engineering and Technology (IET) under licence from the UK regulator, the Engineering Council.

Course content

Throughout the course you’ll choose from a range of optional modules that allow you to pursue topics across electronic and electrical engineering as they relate to your interests or career plans. You could focus on FPGA design for system-on-chip, wireless communications systems nano-electromechanical systems among many others to gain a broad and deep understanding a range of subjects.

A set of core modules will support your learning. You’ll take part in a range of experiments linked to your subject on our lab module, and you’ll develop your skills in programming. If you have no experience of C programming you’ll take the Programming module, or you can take Software Development if you already have those skills.

To build your understanding of the global electronics industry, you’ll also complete a dissertation. This could take the form of a business, manufacturing or outsourcing plan, a proposal for research funding or an essay on a specific aspect of the industry.

Over the summer months you’ll also work on your research project. This may give you the chance to work as an integral part of one of our active research groups, focusing on a specialist topic in computer science and selecting the appropriate research methods.

Want to find out more about your modules?

Take a look at the Electronic and Electrical Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Mini Projects and Laboratory 15 credits
  • Main Project 45 credits

Optional modules

  • Wireless Communications Systems Design 15 credits
  • Micro- and Nano-Electromechanical Systems 15 credits
  • Power Electronics and Drives 15 credits
  • Electric Power Generation by Renewable Sources 15 credits
  • Electric Drives 15 credits
  • FPGA Design for System-on-Chip 15 credits
  • Control Systems Design 15 credits
  • Embedded Microprocessor System Design 15 credits
  • Medical Electronics and E-Health 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Electronic and Electrical Engineering MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The professional project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects by students in the School of Electronic and Electrical Engineering have included:

  • Wireless sensor networks, the internet of things and bicycle traffic in the city.
  • Device to Monitor Activity of Ageing People
  • Wind turbine strain gauge system
  • Wind turbine teaching demonstrator
  • Virtual Machines Placement in Core Networks with Renewable Energy
  • Design and Analysis of High-Performance Internet Routers
  • Spatial Modulation for Massive MIMO System
  • Fuel cell for energy storage
  • Low cost design and fabrication of 3D MEMS components
  • Ultrasonic Wind Speed Detection
  • Core Quantum Networks
  • Microwave Low Noise Amplifier

A proportion of projects are formally linked to industry, and can include spending time at the collaborator’s site over the summer.

Career opportunities

Graduates of this course can expect to find jobs where industry needs a breadth of knowledge matched by a depth in certain areas.

You’ll be well equipped to integrate and co-ordinate the strands of a cross-disciplinary project and manage the interfaces between specialities. With these skills, you’ll be in a good position to progress to project management roles in companies working at the cutting edge of modern multi-faceted systems.

General Electric, AECOM, Deep Sea Electronics, Hyperdrive Innovation, Descon Engineering, Broadcom, Pakistan Oilfields Ltd., Wabtec Rail UK and many others are among the organisations where graduates from our School have found employment.



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Demand for aerospace engineering graduates is rising, both in the UK and overseas. In fact, the UK aerospace industry is the second biggest in the world after the USA, and it’s home to some of the world’s leading aerospace companies such as Airbus, Astrium, BAE Systems, GKN and Rolls-Royce. Read more

Demand for aerospace engineering graduates is rising, both in the UK and overseas. In fact, the UK aerospace industry is the second biggest in the world after the USA, and it’s home to some of the world’s leading aerospace companies such as Airbus, Astrium, BAE Systems, GKN and Rolls-Royce.

Taught by expert academics in a leading research environment, this programme will equip you with the knowledge and skills to succeed in an exciting and challenging sector. You’ll study aerospace structures and structural analysis, along with optional, specialist modules in areas such as aerodynamics and computational fluid dynamics, aircraft design, systems and optimisation methods, rotary wing aircraft and propulsion.

Our Aerospace Engineering Industrial Advisory Board is actively engaged in ensuring this course meets the needs of industry and reflects trends in the sector. It also provides industrial talks and seminars and advice and support to our students during their professional projects.

In addition to our advanced CAD facilities for design work, we have the latest industry-standard software for computational fluid dynamics and finite element modelling of material stress analysis, programming and structural and multidisciplinary optimisation.

Accreditation

We are currently seeking accreditation from the Institute of Mechanical Engineers (IMechE) and the Royal Aeronautical Society.

Course content

You’ll take a compulsory module in Semester 1 which develops your knowledge of aerospace structures and the theory behind aerospace structural analysis, as well as applying this understanding to real-world problems.

This will inform the rest of your studies, where you’ll select from a wide range of optional modules allowing you to pursue the topics that appeal to your interests or suit your future career plans. You could gain sophisticated knowledge in areas such as aerospace vehicle design, computational methods or materials failure analysis.

Throughout the programme you’ll complete your Professional Project – an independent piece of research on a topic within aerospace engineering that allows you to demonstrate your knowledge and skills. In the two taught semesters you’ll review the literature around your topic and plan the project, before completing the design, analysis, computation, experimentation and writing up in the summer months.

Want to find out more about your modules?

Take a look our Aerospace Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Aerospace Structures 15 credits
  • Professional Project 75 credits

Optional modules

  • Materials Selection and Failure Analysis 15 credits
  • Design Optimisation - MSc 15 credits
  • Aerospace Vehicle Design 20 credits
  • Aerodynamics and Aerospace Propulsion 20 credits
  • Finite Element Methods of Analysis 20 credits
  • Mechatronics and Robotics Applications 15 credits
  • Engineering Computational Methods 15 credits
  • Rotary Wing Aircraft 15 credits
  • Vehicle and Product Systems Design 15 credits
  • Computational Fluid Dynamics Analysis 15 credits

For more information on typical modules, read Aerospace Engineering MSc in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The professional project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Typical projects for MSc Aerospace Engineering students could include:

  • Design of a stiffened titanium aircraft structural component for additive manufacturing
  • Development of software based on Swarm Intelligence Methodologies for Structural Optimisation
  • Circulation control using air jets to improve the performance of aircraft wings and wind turbines
  • Design and optimisation of a Flexible Structural Support for a Mars Rover Umbilical Release Mechanism
  • Aerodynamic analysis of the Bloodhound supersonic car using Computational Fluid Dynamics
  • Computational Fluid Dynamics modelling of turbulent combustion processes
  • The control of flow separation using vortex generators

A proportion of projects are formally linked to industry, and can include spending time at the collaborator’s site over the summer.

Career opportunities

The aerospace industry is one of the most successful parts of UK engineering and is truly global in nature.

You’ll be able apply the skills you gain from this course to numerous areas of the aerospace industry, such as aerospace fundamental research, airline management and operations, satellite operations, aerospace design and manufacture in both the civil and military environments and Formula 1 racing.

Whether you join an aerospace company in the UK, such as Airbus, BAE Systems or Rolls-Royce or choose to work elsewhere in the world, the foundation provided by the MSc will make sure you are prepared for a rewarding and challenging career.

Links with industry

During this course you will meet employers from organisations operating within this sector through seminars and talks and by attending our careers fair. In previous years there have been talks from colleagues at Airbus, Astrium, BAE Systems, Rolls-Royce to provide additional industrial perspectives to the course and career guidance to students. 



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If you are an ambitious engineering graduate – from a civil, mechanical, computing or electronic engineering background – this course is a smart route to a career in the expanding field of transport consultancy and public policy. Read more

If you are an ambitious engineering graduate – from a civil, mechanical, computing or electronic engineering background – this course is a smart route to a career in the expanding field of transport consultancy and public policy.

97% of our graduates find employment in a professional or managerial role, or continue with further studies.*

Learn to develop solutions to engineering problems that fit the broader aims of transport and planning policy, from academics with an international reputation whose research sets industry standards. This includes studying the principles of transport engineering and data collection and analysis. Other options include:

  • Traffic management
  • Road geometry and infrastructure
  • System dynamics
  • Road safety management
  • Public transport planning.

Develop an early understanding of four-stage modelling before gaining hands-on experience of SATURN and other Leeds-built models so that you become fluent in their use in live environments.

Deepen your knowledge of:

  • Engineering design principles
  • Integrated transport networks - road, rail, and aviation
  • Refining models to fit local contexts.

And experience what it is like to be part of a project team working across disciplinary boundaries within the transport sector. Through this, gain insights into how engineering, planning, economics, environmental science and modelling can work together to develop sustainable solutions to global challenges. This industry-inspired approach will enable you to apply your knowledge to real-world issues in the field.

Your colleagues will be among the best and brightest from Latin America to the Far East, from Africa to Europe and the UK. Together you will learn engineering techniques that will help you develop transport networks that are founded on fundamental principles, robust evidence, sustainable and equitable principles, state-of-the-art modelling, accurate data analysis, and an understanding of human psychology.

This course provides you with a clear pathway to the Transport Planning Professional (TPP) qualification and is accredited by the major professional bodies in the transport sector, including Chartered Institute of Logistics and Transport (CILT UK) and Chartered Institution of Highways and Transport (CIHT).

ITS – the global institute teaching the transport leaders of tomorrow.

*Higher Education Statistics Agency (HESA), Destinations of Leavers from Higher Education (DLHE) 2015, http://www.hesa.ac.uk

We have redesigned our suites of courses following close consultation with Industry and academia.

With a strong focus on industry needs, our degrees will prepare you for employment in your chosen field. They will also address the multi-disciplinary nature of transport – enabling you to make effective decisions for clients, employers and society.

And to experience what it’s really like to work in the transport sector, collaborate with a project team of students from our other degrees through our new Transport Integrated Project module.

Research environment

The Institute for Transport Studies (ITS) was established as the UK’s first multi-disciplinary transport department, and we continue to lead the field with our research.

Our reputation allows us to invest in world-class facilities, such as the University of Leeds Driving Simulator – one of the most sophisticated in any university in the world, allowing us to research driver behaviour in controlled lab conditions. We also have access to a variety of specialist software tools including those we’ve developed in-house such as SATURN, PLUTO, DRACULA, MARS and KonSULT.

Other Study Options

This programme is available part time, allowing you to combine study with other commitments. You can work to fund your studies, or gain a new qualification without giving up an existing job. We aim to be flexible in helping you to put together a part-time course structure that meets your academic goals while recognising the constraints on your study time.

You can also study this subject at Postgraduate Diploma level, part time or full time, or at Postgraduate Certificate level with our PGCert in Transport Studies.

Accreditation

This programme is recognised by the major professional bodies in the transport sector. It fulfils the educational requirements for membership of the Chartered Institute of Logistics and Transport (CILT UK) and the Chartered Institution of Highways and Transportation (CIHT) and provides a pathway towards the Transport Planning Professional (TPP) qualification.

It is also accredited as meeting the requirements for technical Further Learning for Chartered Engineer (CEng) status for candidates who have already acquired a CEng accredited BEng (Hons). Please see the Joint Board of Moderators website for further information.

Course structure

Compulsory modules

  • Shaping Future Transport Systems 15 credits
  • Principles of Transport Modelling 15 credits
  • Transport Data Collection and Analysis 15 credits
  • Principles of Transport Engineering 15 credits
  • Transport Dissertation 60 credits
  • Transport Integrated Project 15 credits

Optional modules

  • Public Transport Planning and Management 15 credits
  • System Dynamics: Modelling Policy 15 credits
  • Traffic Management 15 credits
  • Road Geometry and Infrastructure 15 credits
  • Traffic Network Modelling 15 credits
  • Deterioration and Maintenance of Pavements 15 credits

For more information on typical modules, read Transport Planning and Engineering MSc(Eng) Full Time in the course catalogue

For more information on typical modules, read Transport Planning and Engineering MSc(Eng) Part Time in the course catalogue

Learning and teaching

Postgraduate study involves a range of teaching methods, supported by independent learning. In addition to the traditional lecture and seminar formats, you’ll experience a blend of workshops, computer exercises, practical sessions, directed reading, reflective journal, student-led discussions, fieldwork and tutorials.

Assessment

Assessment is equally varied and can include coursework essays, case-study reports, group assignments, posters, presentations and exams.

Career opportunities

Links with industry

ITS has close working relationships with a number of organisations and many employers visit ITS each year to interview our students for graduate schemes and other vacancies. ITS also regularly circulates specific job vacancies to students.

Our students are highly sought after and have a good reputation with transport consultants, and may receive a job offer before or shortly after graduation.



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This course provides consultants, operators, regulators and managers with the professional skills and training to contribute to the provision of environmentally sound and economically sustainable systems in the fields of clean water supply, wastewater treatment, and the management of solid waste, including wastes from the oil industry. Read more

This course provides consultants, operators, regulators and managers with the professional skills and training to contribute to the provision of environmentally sound and economically sustainable systems in the fields of clean water supply, wastewater treatment, and the management of solid waste, including wastes from the oil industry.

It is intended for those who find themselves in management positions with little experience of the techniques necessary to manage the range of projects for which they have responsibilities, or people with a background in management who feel they lack up-to-date technical knowledge in the rapidly changing field of environmental engineering.

You’ll build your knowledge of key issues such as water resource, solid waste or health management. Taught by experts in a research-intensive environment, you’ll gain an insight into the latest developments in this exciting field and prepare to meet the challenges they bring.

You’ll study a broad programme informed by an employers’ group and our Industrial Advisory Board, ensuring that we equip you with the skills you need in the modern engineering industry.

You’ll also benefit from using our specialist facilities, such as our public health labs with separate areas for solid waste, water and wastewater, and a class II microbiology lab and clean room. We have all the specialist software you’ll need for your programme, and you’ll have access to a dedicated study suite for Masters students.

Accreditation

This degree is accredited by the Joint Board of Moderators as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired a partial CEng accredited undergraduate first degree.

This course is also accredited by EUR-ACE, the European quality label for engineering degree programmes at Bachelor and Master level.

Course content

A series of core modules that run throughout the year will develop your knowledge of a wide range of topics.

You’ll explore the diversion of organic wastes from landfill and how energy is recovered from them, as well as water supply systems, the challenges of water resource management and the different landfill, mechanical-biological and thermal treatment options available for solid waste.

You’ll also consider wastewater treatment, solid waste management and issues such as controlling emissions. The ways in which legislation is used to protect the environment and the role of public health engineers are also among the topics you’ll cover.

Over the summer months you’ll also research a topic of your choice in environmental engineering and project management – this independent research project will demonstrate your skills, and could even lay the groundwork for your future career specialism.

Want to find out more about your modules?

Take a look at the Environmental Engineering and Project Management module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Water Resource Management 15 credits
  • Indoor and Urban Air Quality 15 credits
  • Advanced Wastewater Management 15 credits
  • Solid Waste Management 15 credits
  • Groundwater Pollution and Contaminated Land 15 credits
  • Environmental Engineering and Project Management Dissertation 60 credits
  • Environmental Microbiology 15 credits
  • Circular Economy and Resource Recovery from Waste 15 credits
  • Project and Asset Management 15 credits

For more information on typical modules, read Environmental Engineering and Project Management MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The dissertation project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Project by students in MSc Environmental Engineering and Project Management have included:

  • Potential impacts of climate change for wastewater treatment
  • Membrane bioreactors for industrial applications
  • The use of recycled glass in wastewater treatment
  • Settlement of activated sludge and the influence of ballasted settlement aids

A proportion of projects are formally linked to industry, and may include spending time at the collaborator’s site over the summer.

Career opportunities

This programme will equip you with a variety of knowledge and skills that are in demand from a number of professions.

Graduates are likely to work for consulting and contracting engineers, water companies, utility companies and regulators as well as other environment-related companies. Previous graduates have gone to work in a range of roles for companies such as Veolia Water, Lilongwe Water Board, Enviro Care India Pvt. Ltd and a range of national and governmental bodies in countries worldwide.



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