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This is the only programme of its kind in the UK, giving you high-level skills and training across the rapidly developing area of carbon capture and storage (CCS). Read more

Programme description

This is the only programme of its kind in the UK, giving you high-level skills and training across the rapidly developing area of carbon capture and storage (CCS).

Global energy demands are still rising, and fossil fuels remain central to meeting those demands in the medium term. CCS is a recognised solution to reducing CO2 emissions until fossil fuels are entirely replaced by renewable energy technologies.

With commercial trials under way, countries and industries are investing in this new technology. In the UK, all existing power stations must have a full-scale retrofit of CCS within five years of the technology being independently judged as technically and commercially proven.

This MSc draws on our world-class interdisciplinary academic research and the insights we have gained from projects involving our industrial stakeholders.

This programme is affiliated with the University's Global Environment & Society Academy.

Programme structure

The MSc has two semesters of lectures and practical classes, followed by a research dissertation of up to 15,000 words. The programme includes industry guest lectures as well as opportunities for fieldwork and industry site visits to a range of locations.

Designed for graduates of engineering or geoscience-related subjects, the programme provides high-level skills and training in the entire value chain of CCS, including combustion, transport, geoscience and legal aspects.

Compulsory courses typically include*:
•Carbon Economics
•Carbon Capture and Transport
•Hydrocarbons (compulsory for students without a geoscience background)
•Carbon Storage and Monitoring
•Dissertation
•Geology for Earth Resources (compulsory for students without a geoscience background)

Option courses:

In consultation with the Programme Director, you will choose from a range of option courses*. We particularly recommend:
•Fundamentals for Remote Sensing
•Novel Strategies for Carbon Storage in Soil
•SeismicReflection Interpretation
•Energy & Society
•Geology for Earth Resources
•Principles of Geographical Information Science
•Spatial Modelling
•Understanding Environment and Development
•Climate Change and Corporate Strategy
•Energy Policy and Politics
•Hydrocarbon Reservoir Quality
•Introduction to Radar Remote Sensing
•Political Ecology
•Separation Processes For Carbon Capture
•Technology and Innovation Management

*Please note that courses are offered subject to timetabling and availability and are subject to change each year.

Career opportunities

Graduates can enter into all manner of jobs due to the transferable and highly desirable nature of the skills gained. However, typically our graduates pursue careers in business, industry, government and non-governmental organisations in the field of low-carbon energy production.

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The MSc portfolio within our Energy & Power programme has recently been reviewed. This is to ensure that our courses are attractive to prospective students and to make sure that the courses titles and student learning outcomes are relevant to future employers. Read more
The MSc portfolio within our Energy & Power programme has recently been reviewed. This is to ensure that our courses are attractive to prospective students and to make sure that the courses titles and student learning outcomes are relevant to future employers. As a result of the review we are launching new course titles, reorganising and renaming some courses and withdrawing others.

As part of this review, the decision has been taken to remove Carbon Capture and Storage from our portfolio for 2017/18 registration. We are confident that we can offer a suitable and exciting replacement and believe that the Advanced Chemical Engineering MSc is most closely aligned to this course. Below are the available MSc’s in our Energy & Power programme:

Advanced Mechanical Engineering
Design of Rotating Machines
Energy Systems & Thermal Processes
Flow Assurance for Oil & Gas Production
Process Systems Engineering
Energy from Waste
Offshore Materials Engineering
Offshore Pipeline Engineering
Offshore Risk Management
Offshore Subsea Engineering
Renewable Energy Engineering
Renewable Energy Technology
Offshore Renewable Energy
Geothermal Engineering.

Alternatively if you would like to discuss your options further please email

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The University of Birmingham, as a partner in The Midlands Energy Graduate School (MEGS), has launched a new taught Masters in Efficient Fossil Energy Technologies. Read more
The University of Birmingham, as a partner in The Midlands Energy Graduate School (MEGS), has launched a new taught Masters in Efficient Fossil Energy Technologies.

Consisting of core and optional modules, delivered by experts from the universities of Nottingham, Birmingham and Loughborough, this MSc will encourage and embed excellence in fossil energy technologies, carbon capture and efficient combustion. It will prepare future leaders and industrial engineers with knowledge and skills to tackle the major national and international challenges of implementing new fossil-based power plant and processes more efficiently, with near zero emissions and CO2 capture.

This course provides expert teaching from three leading universities in the UK a unique partnership to allow students to benefit from a wide range of expertise. Modules studied represent the academic specialism offered by each university and the research project, taken at the university where you register, will focus on specific aspects of fossil energy technologies: Birmingham specialises in managing chemical reactions, plant design and carbon capture technologies; Loughborough in materials technologies for power generation and high-temperature applications; and Nottingham will focus on combustion technologies, power generation, environmental control and carbon capture. It is therefore important to select your choice of university carefully. Full details of these options and specialisms are in the Modules section of the Course Details tab and all enquiries are welcome.

Chemical Engineering is dynamic and evolving. It provides many solutions to problems facing industries in the pharmaceutical, biotechnological, oil, energy and food and drink sectors. It is vital to many issues affecting our quality of life; such as better and more economical processes to reduce the environmental burden, and more delicious and longer lasting food due to the right combination of chemistry, ingredients and processing.

Birmingham is a friendly, self-confident, School which has one of the largest concentrations of chemical engineering expertise in the UK. The School is consistently in the top five chemical engineering schools for research in the country.

About the School of Chemical Engineering

Birmingham has one of the largest concentrations of Chemical Engineering expertise in the UK, with an excellent reputation in learning, teaching and research.
Investment totalling over £3.5 million in our buildings has resulted in some of the best teaching, computing and laboratory facilities anywhere in the UK.
We have achieved an excellent performance in the Research Excellence Framework (REF) – the system for assessing the quality of research in UK higher education institutions. 87% of the research in the School was rated as world-leading or internationally excellent. It was ranked joint fourth overall in the UK for its research prowess and first nationally for research impact.
The enthusiasm that the academic staff have for their research comes through in their teaching and ensures that they and you are at the cutting edge of chemical engineering.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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Programme description. This programme will give you a fundamental understanding of the issues affecting the Earth enabling you to play a vital role in devising and enacting strategies to protect and conserve the environment, both in Europe and beyond. Read more

Programme description

This programme will give you a fundamental understanding of the issues affecting the Earth enabling you to play a vital role in devising and enacting strategies to protect and conserve the environment, both in Europe and beyond.

Human activities are recognised as having an increasingly significant effect on the Earth’s biosphere. Our use of natural resources, deforestation, soil erosion, the release of potentially toxic compounds and pathogens, and the increase in greenhouse gases are all examples of pressures that have potentially serious consequences for humanity and other life on Earth.

On this programme you will learn about the issues that face the Earth and gain an in-depth understanding of natural resource management and the processes that give rise to environmental degradation and pollution problems.

It will allow you to play a vital role in planning and putting into action strategies to protect and conserve the environment.

This programme is run in collaboration with Scotland’s Rural College (SRUC).

This programme is affiliated with the University's Global Environment & Society Academy.

Programme structure

This programme involves two semesters of taught courses, which are a balance of lectures, seminars, workshops and visits, plus a research dissertation project of about 16,000 words.

Compulsory courses typically include:

•Atmospheric Quality and Global Change

•Analysing the Environment

•Land Use/Environmental Interactions

•Analysing the Environment Study Tour

•Dissertation

Option courses:

In consultation with the Programme Director, you will choose from a range of option courses*. We particularly recommend:

•Soil Protection and Management

•Integrated Resource Management

•Ecosystem Dynamics and Functions

•Marine Systems and Policies

•Archives: History, Geography, Politics

•Carbon Capture and Transport

•Culture, Ethics & Environment

•Encountering Cities

•Environmental Geochemistry

•Foundations in Ecological Economics

•Human Dimensions of Environmental Change and Sustainability

•Principles of Environmental Sustainability

•Principles of GIS

•Project Appraisal

•Understanding Environment and Development

•Values and the Environment

•Environmental Impact Assessment

•Waste Reduction and Recycling

•Sustainability of Food Production

•Participation in Policy and Planning

•Forests and Environment

•Carbonate Sequence Stratigraphy

•Climate Change and Corporate Strategy

•Hyperspectral Remote Sensing

•Integrated Resource Planning

•Introduction to Environmental Modelling

•Political Ecology

•Ecosystem Values and Management

•Soil Science Concepts and Application

•Water Resource Management

Field trip

This programme typically includes a week-long study tour in spring. Past study tours have been held in France, Greece, Portugal, Israel and Morocco.

Learning outcomes

Students will:

•develop a scientific understanding of some of the major processes which influence the quality of land, air and water resources

•acquire knowledge of the most effective methods of environmental protection

•develop expertise in the design and implementation of programmes of environmental protection

•have the opportunity to study the integrated protection and management of particular ecosystems or resources

Career opportunities

Our graduates have a solid record in finding employment in the environmental sector while some choose to further their studies through a PhD.

There are also opportunities in consultancy positions and with environmental regulators, government and NGOs.



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Accredited by the the Institution of Chemical Engineers. Whether you’re already working in the field or just starting out, this course will deepen your understanding and equip you with skills and expertise in process safety, loss prevention and risk assessment. Read more

About the course

Accredited by the the Institution of Chemical Engineers

Whether you’re already working in the field or just starting out, this course will deepen your understanding and equip you with skills and expertise in process safety, loss prevention and risk assessment. You’ll be ready for a career in the oil and gas, chemical, nuclear and pharmaceutical industries, or with any of the consultancies that service them.

Take advantage of our expertise

Our teaching is grounded in specialist research expertise. Our reputation for innovation secures funding from industry,
UK research councils, the government and the EU. Industry partners, large and small, benefit from our groundbreaking work addressing global challenges.

You’ll have access to top facilities, including modern social spaces, purpose-built labs, the Harpur Hill Research Station for large-scale work, extensive computing facilities and a modern applied science library. There are high-quality research facilities for sustainable energy processes, safety and risk engineering, carbon capture and utilisation, and biological processes and biomanufacturing.

Studentships

Contact us for current information on available scholarships.

Course content

Diploma: three core modules and five optional modules. MSc(Eng): one core module, major research project, and five optional modules.

Core modules

Process Safety Management and Loss Prevention
Introduction to Hazard Analysis and Risk Assessment
Hazards in Process Plant Design and Operation
Dissertation (for MSc)

Examples of optional modules

Process Plant Reliability and Maintainability
Human Error and Human Behaviour
Applied Hazard and Operability Studies (HAZOP)
Safety in Nuclear Operations
Computer Control: Safe Practice
Process Safety in the Oil and Gas Industry
Process Safety in the Pharmaceutical, Food and Consumer Products

Full-time or part-time

This course is available full-time over a year, or part-time over two or three years. Each module can be taken as a short course – useful if you’re already working in industry.

Part-time students need to complete all modules within two years. You can take an extra third year to complete your dissertation if you need to – we won’t charge fees for that year. Modules are delivered about once per month from September to June. Each module is four days long. You must therefore attend for 32 days in total.

Teaching and assessment

We use a mixture of lessons and discussions, real-life case studies, workshops and hands-on computer sessions. Continuous assessment is based on assignments for each module, and a dissertation.

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Accredited by the Energy Institute and the Institution of Chemical Engineers. Tailor the course to suit you by blending core and optional modules. Read more

About the course

Accredited by the Energy Institute and the Institution of Chemical Engineers

Tailor the course to suit you by blending core and optional modules. This practical degree has been developed with the Institution of Chemical Engineers and the Energy Institute to equip you with the skills and expertise needed for work in sectors including industry, education, public administration and commerce.

Take advantage of our expertise

Our teaching is grounded in specialist research expertise. Our reputation for innovation secures funding from industry,
UK research councils, the government and the EU. Industry partners, large and small, benefit from our groundbreaking work addressing global challenges.

You’ll have access to top facilities, including modern social spaces, purpose-built labs, the Harpur Hill Research Station for large-scale work, extensive computing facilities and a modern applied science library. There are high-quality research facilities for sustainable energy processes, safety and risk engineering, carbon capture and utilisation, and biological processes and biomanufacturing.

Studentships

Contact us for current information on available scholarships.

Course content

Diploma: five core and three optional modules. MSc(Eng): five core modules, major research or design project, and three optional modules.

Core modules

Introduction to Fuel and Energy
Applied Energy Engineering
Environment: Gaseous Emissions
Environment: Particulate Emissions
Environment: Liquid Effluents
Research Project

Examples of optional modules

Computational Fluid Dynamics
Fires and Explosion Dynamics
Energy from Biomass and Waste
Low Carbon Energy and Technology (Renewables)
Environmental Impacts and Protection
Nuclear Reactor Engineering
Oil and Gas Origins and Usage

Teaching and assessment

We use lectures, tutorials and project work. All your tutors are actively involved in research and consultancy in their field. Assessment is by formal examinations and a research or design project dissertation. Continuous assessment of some modules.

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Accredited by the the Institution of Chemical Engineers. Develop the essential skills for a career in bioindustry or for further advanced research in next-horizon biotechnologies. Read more

About the course

Accredited by the the Institution of Chemical Engineers

Develop the essential skills for a career in bioindustry or for further advanced research in next-horizon biotechnologies. You’ll learn from world-class researchers, including staff from Biomedical Science and Materials Science and Engineering. Our graduates work in biotechnology, biopharmaceutical and bioprocess organisations.

Take advantage of our expertise

Our teaching is grounded in specialist research expertise. Our reputation for innovation secures funding from industry,
UK research councils, the government and the EU. Industry partners, large and small, benefit from our groundbreaking work addressing global challenges.

You’ll have access to top facilities, including modern social spaces, purpose-built labs, the Harpur Hill Research Station for large-scale work, extensive computing facilities and a modern applied science library. There are high-quality research facilities for sustainable energy processes, safety and risk engineering, carbon capture and utilisation, and biological processes and biomanufacturing.

Studentships

Contact us for current information on available scholarships.

Course content

Four core modules including research project, a conversion module, and three optional modules.

Core modules

Biopharmaceutical Bioprocessing
Biosystems Engineering and Computational Biology
Bioanalytical Techniques
Research Project

Examples of optional modules

Any three from:

Microfluidics
Bio-energy
Synthetic Biology
Tissue Engineering Approaches to Failure in Living Systems
Bionanomaterials
Stem Cell Biology
Proteomics and Bioinformatics

Conversion modules:

Principles in Biochemical Engineering or
Principles in Biomolecular Sciences.

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Our Energy programmes allow you to specialise in areas such as bio-energy, novel geo-energy, sustainable power, fuel cell and hydrogen technologies, power electronics, drives and machines, and the sustainable development and use of key resources. Read more
Our Energy programmes allow you to specialise in areas such as bio-energy, novel geo-energy, sustainable power, fuel cell and hydrogen technologies, power electronics, drives and machines, and the sustainable development and use of key resources.

We can supervise MPhil projects in topics that relate to our main areas of research, which are:

Bio-energy

Our research spans the whole supply chain:
-Growing novel feedstocks (various biomass crops, algae etc)
-Processing feedstocks in novel ways
-Converting feedstocks into fuels and chemical feedstocks
-Developing new engines to use the products

Cockle Park Farm has an innovative anaerobic digestion facility. Work at the farm will develop, integrate and exploit technologies associated with the generation and efficient utilisation of renewable energy from land-based resources, including biomass, biofuel and agricultural residues.

We also develop novel technologies for gasification and pyrolysis. This large multidisciplinary project brings together expertise in agronomy, land use and social science with process technologists and engineers and is complemented by molecular studies on the biology of non-edible oilseeds as sources for production of biodiesel.

Novel geo-energy

New ways of obtaining clean energy from the geosphere is a vital area of research, particularly given current concerns over the limited remaining resources of fossil fuels.

Newcastle University has been awarded a Queen's Anniversary Prize for Higher Education for its world-renowned Hydrogeochemical Engineering Research and Outreach (HERO) programme. Building on this record of excellence, the Sir Joseph Swan Centre for Energy Research seeks to place the North East at the forefront of research in ground-source heat pump systems, and other larger-scale sources of essentially carbon-free geothermal energy, and developing more responsible modes of fossil fuel use.

Our fossil fuel research encompasses both the use of a novel microbial process, recently patented by Newcastle University, to convert heavy oil (and, by extension, coal) to methane, and the coupling of carbon capture and storage (CCS) to underground coal gasification (UCG) using directionally drilled boreholes. This hybrid technology (UCG-CCS) is exceptionally well suited to early development in the North East, which still has 75% of its total coal resources in place.

Sustainable power

We undertake fundamental and applied research into various aspects of power generation and energy systems, including:
-The application of alternative fuels such as hydrogen and biofuels to engines and dual fuel engines
-Domestic combined heat and power (CHP) and combined cooling, heating and power (trigeneration) systems using waste vegetable oil and/or raw inedible oils
-Biowaste methanisation
-Biomass and biowaste combustion, gasification
-Biomass co-combustion with coal in thermal power plants
-CO2 capture and storage for thermal power systems
-Trigeneration with novel energy storage systems (including the storage of electrical energy, heat and cooling energy)
-Engine and power plant emissions monitoring and reduction technology
-Novel engine configurations such as free-piston engines and the reciprocating Joule cycle engine

Fuel cell and hydrogen technologies

We are recognised as world leaders in hydrogen storage research. Our work covers the entire range of fuel cell technologies, from high-temperature hydrogen cells to low-temperature microbial fuel cells, and addresses some of the complex challenges which are slowing the uptake and impact of fuel cell technology.

Key areas of research include:
-Biomineralisation
-Liquid organic hydrides
-Adsorption onto solid phase, nano-porous metallo-carbon complexes

Sustainable development and use of key resources

Our research in this area has resulted in the development and commercialisation of novel gasifier technology for hydrogen production and subsequent energy generation.

We have developed ways to produce alternative fuels, in particular a novel biodiesel pilot plant that has attracted an Institution of Chemical Engineers (IChemE) AspenTech Innovative Business Practice Award.

Major funding has been awarded for the development of fuel cells for commercial application and this has led to both patent activity and highly-cited research. Newcastle is a key member of the SUPERGEN Fuel Cell Consortium. Significant developments have been made in fuel cell modelling, membrane technology, anode development and catalyst and fuel cell performance improvements.

Facilities

As a postgraduate student you will be based in the Sir Joseph Swan Centre for Energy Research. Depending on your chosen area of study, you may also work with one or more of our partner schools, providing you with a unique and personally designed training and supervision programme.

You have access to:
-A modern open-plan office environment
-A full range of chemical engineering, electrical engineering, mechanical engineering and marine engineering laboratories
-Dedicated desk and PC facilities for each student within the research centre or partner schools

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The programme provides advanced studies in chemical engineering, reflecting the research expertise and scholarship within the Department of Chemical & Environmental Engineering. Read more
The programme provides advanced studies in chemical engineering, reflecting the research expertise and scholarship within the Department of Chemical & Environmental Engineering. Relevance to industry is a strong feature of this course which offers a unique combination of science and engineering skills.

It offers graduates with a Bachelor level (BEng) accredited degree the further learning requirement for chartership. The department provides a strong and dynamic environment with close links between research and teaching. Students on this programme will be able to think and function in an integrated manner across the area of chemical engineering.

This course is accredited by the Chartered Institute of Chemical Engineers( IChemE) and is designed to meet the UK-SPEC requirements of IChemE for those students who already hold BEng, BSc or non-accredited chemical engineering degree and wish to proceed to chartered status.

You will gain skills in advanced engineering practice, which includes design, operations, problem-solving and practical elements. The advanced practice is centred on themes in energy and environmental applications, so you can gain significant experience in areas such as petroleum processing, energy efficiency, carbon capture and water treatment.

Students will develop:
skills in research, project management, problem solving and reporting
ability to communicate ideas effectively in written reports, verbally and by means of presentations to groups
ability to exercise original thought
ability to plan and undertake an individual project
interpersonal communication and professional skills

Previous research projects have included:

Electricity Storage
Microwave Processing of Hydrocarbons
Novel Mineral Traps to permanently sequester CO2
Application of advanced measurement techniques to bubble columns


Scholarship information can be found at /http://www.nottingham.ac.uk/graduateschool/funding/index.aspx

This course is also taught at The University of Nottingham Malaysia Campus

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The global challenges of climate and energy require new technologies for renewable energy sources, methods of energy storage, efficient energy use, new lightweight vehicular structures, techniques for carbon capture and storage and climate engineering. Read more
The global challenges of climate and energy require new technologies for renewable energy sources, methods of energy storage, efficient energy use, new lightweight vehicular structures, techniques for carbon capture and storage and climate engineering. This is a broad-based MSc, designed for graduates who wish to acquire skills in energy and materials science in order to participate in the emerging challenges to meet climate change targets.

Degree information

Students gain an advanced knowledge of materials science as it applies to energy and environmental technologies and research skills including information and literature retrieval, critical interpretation and analysis, and effective communication. They can benefit from modules in chemistry, physics, chemical engineering or mechanical engineering, thus offering future employers a wide-ranging skills base. Graduates will be well qualified to deal with the problems of energy decision-making and the implications for the environment.

Students undertake modules to the value of 180 credits. The programme consists of five core modules (90 credits), two optional modules (15 credits each) and a research project (60 credits). An exit-level only Postgraduate Diploma (120 credits) is available. An exit-level only Postgraduate Certificate (60 credits) is available.

Core modules - students take all of the following, totalling 90 credits, and a 60 credit research dissertation.
-Advanced Topics in Energy Science and Materials
-Microstructural Control in Materials Science
-Energy Systems and Sustainability
-Transferable Skills for Scientists
-Research Project Literature Review

Optional modules - students take 30 credits drawn from the following:
-Climate and Energy
-Materials and Nanomaterials
-Electrical Power Systems and Alternative Power Systems
-Atom and Photon Physics
-Solid State Physics
-Mastering Entrepreneurship

Dissertation/report
All MSc students undertake an independent research project which culminates in a dissertation of approximately 10,000 words, an oral presentation and a viva voce examination (60 credits).

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials, laboratory classes and research supervision. Assessment is through unseen written examination and coursework. The literature project is assessed by written dissertation and oral presentation, and the research project is assessed by a written report, an oral presentation and a viva voce examination.

Careers

The UK has committed to 80% reduction in CO2 emissions on a 1990 baseline by 2050. CERES, the organisation that represents the largest institutional investors would like to see 90% reduction by 2050. National Systems of Innovation (NSI), which includes the universities, research centres and government departments working in conjunction with industry, will need to apprehend new opportunities and change direction, diverting personnel to energy and climate issues in response to changing markets and legislation. This MSc will contribute to the supply of personnel needed for the era of sustainability.

Top career destinations for this degree:
-Process Innovation Executive, Samsung Electronics UK
-Chemical Engineer, Jing Eong Fang
-Research Intern, CECP
-PhD Nanomaterials, University of Oxford
-PhD Sugar Chemistry, Monash University

Why study this degree at UCL?

This programme is designed for graduates from a wide range of science and engineering backgrounds who wish to broaden their knowledge and skills into materials science with an emphasis on the energy and climate change issues that will drive markets over the next century. It delivers courses from five departments across three faculties depending on options and includes a self-managed research project which is intended to introduce the challenges of original scientific research in a supportive environment.

Research activities span the whole spectrum of energy-related research from the development of batteries and fuel cells to the prediction of the structure of new water-splitting catalytic materials.

Students develop experience in scientific method, techniques for reporting science and in the many generic skills required for a future career.

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The MPhil and PhD programmes in Chemical Engineering attract students from diverse disciplinary backgrounds such as statistics, maths, electrical engineering, chemistry and physics. Read more
The MPhil and PhD programmes in Chemical Engineering attract students from diverse disciplinary backgrounds such as statistics, maths, electrical engineering, chemistry and physics. You may work on multidisciplinary research projects in collaboration with colleagues across the University or from external organisations.

Research in the School of Chemical Engineering and Advanced Materials is cross-disciplinary and our strategy is to ensure that our research groups grow and provide a balanced portfolio of activities for the future. This is achieved in part through MPhil and PhD supervision.

Advanced materials

Every article, instrument, machine or device we use depends for its success upon materials, design and effective production. We work on a wide range of materials topics including:
-New material development
-Optimising of materials processing
-Testing and evaluation at component scale and at high spatial resolution
-Modelling
-Failure analysis

Much of our work relates to materials and processes for renewable energy generation, energy efficiency, carbon capture and storage. We also use biological and bio-inspired processes to develop new functional materials.

The Group Head is Professor Steve Bull, Cookson Group Chair of Materials Engineering – high spatial resolution mechanics. His research focuses on development and testing of compliant and porous materials, and the use of sustainable materials. Professor Bull is the 2013 recipient of the Tribology Silver Medal presented by the Tribology Trust, the top national award in this area.

Electrochemical engineering science

Electrochemical Engineering Science (EES) arose out of the pioneering fuel cell research at Newcastle in the 1960s. We are continuing this research on new catalyst and membrane materials, optimising electrode structures and developing meaningful fuel cell test procedures.

We are investigating electrochemical methods for surface structuring, probing and testing at the micron and nanoscale. More recently, we have been using electrochemical analysis to understand cellular and microbial catalysis and processes.

Applications of our research are in:
-Energy production and storage
-Micro and nanoscale device fabrication
-Medical and health care applications
-Corrosion protection

The Group Head is Professor Sudipta Roy. Professor Roy's research focuses on materials processing, micro/nano structuring and corrosion.

Process intensification

Process intensification is the philosophy that processes can often be made smaller, more efficient and safer using new process technologies and techniques, resulting in order of magnitude reductions in the size of process equipment. This leads to substantial capital cost savings and often a reduction in running costs.

The Group Head is Professor Adam Harvey. Professor Harvey's research focuses on Oscillatory Baffled Reactors (OBRs), biofuel processing and heterogeneous catalysis.

Process modelling and optimisation

Our goal is to attain better insight into process behaviour to achieve improved process and product design and operational performance. The complexity of the challenge arises from the presence of physiochemical interactions, multiple unit operations and multi-scale effects.

Underpinning our activity is the need for improved process and product characterisation through the development and application of process analytical techniques, hybrid statistical and empirical modeling and high throughput technologies for chemical synthesis.

The Group Head is Professor Elaine Martin. Professor Martin's research focuses on Process Analytical Technologies, Statistical and Empirical Process Data Modelling, and Process Performance Monitoring.

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This is the first masters level degree course that brings academic rigour and focus to this multi-disciplinary subject. The MSc in Flow Assurance for Oil and Gas Production is suitable for engineering and applied science graduates who wish to embark on successful careers in the oil and gas industry. Read more
This is the first masters level degree course that brings academic rigour and focus to this multi-disciplinary subject. The MSc in Flow Assurance for Oil and Gas Production is suitable for engineering and applied science graduates who wish to embark on successful careers in the oil and gas industry. Our strategic links with industry ensures that all the materials taught on the course are relevant, timely and meets the needs of organisations competing within the sector. This industry-led education makes our graduates some of the most desirable the world for energy companies to recruit.

In the foreseeable future, hydrocarbon (oil and gas) will still be the major energy source irrespective of the developments in renewable and nuclear energy. The term ‘flow assurance’ was coined by Petrobras in the early 1990s meaning literally “guarantee of flow.” It covers all methods to ensure the safe and efficient delivery of hydrocarbons from the well to the collection facilities. It is a multi-disciplinary activity involving a number of engineering disciplines including mechanical, chemical, process, control, instrumentation and software engineering.

Previously uneconomical fields are now being exploited - oil and gas are produced in hostile environments from deep water to the Arctic. As conventional oil reserves decline, companies are developing unconventional oil fields with complex fluid properties. All of these factors mean that flow assurance plays an increasingly important role in the oil and gas industry.

Course overview

The MSc in Flow Assurance for Oil and Gas Production is made up of nine compulsory taught modules (eight compulsory and one optional from a selection of three), a group project and an individual research project.

In addition to management, communication, team work and research skills, each student will attain at least the following outcomes from this degree course:

- Develop a professional ability to undertake a critical appraisal of technical and/or commercial literature.
- Demonstrate an ability to manage research studies, and plan and execute projects in the area of oil and gas production technology and flow assurance.
- Use of the techniques appropriate for the management of a oil and gas production and transport systems.
- Gain an in-depth understanding of the technical, economic and environmental issues involved in the design and operation of oil and gas production and transport systems.

Group project

The group project runs between February and April and is designed to give students invaluable experience of delivering a project within an industry structured team. The project is sponsored by industrial partners who provide particular problems linked to their plant operations. Projects generally require the group to provide a solution to the operational problem. This group project is shared across the Process Systems Engineering MSc, Flow Assurance MSc and Carbon Capture and Transport MSc, giving the added benefit of gaining new insights, ways of thinking, experience and skills from students with other backgrounds.

During the project you will develop a range of skills including learning how to establish team member roles and responsibilities, project management, and delivering technical presentations. All groups submit a written report and deliver a presentation to the industry partner. Part-time students will take an additional elective module instead of the group project.

It is clear that the modern design engineer cannot be divorced from the commercial world. In order to provide practice in this matter, a poster presentation will be required from all students. This presentation provides the opportunity to develop presentation skills and effectively handle questions about complex issues in a professional manner.

Recent Group Projects include:

- Waste water treatment process design
- A new operation mode design for a gas processing plant.

Individual Project

The individual research project allows students to delve deeper into a specific area of interest. Our industrial partners often put forward practical problems or areas of development as potential research topics. For part-time students, their research project is usually undertaken in collaboration with their place of work. The individual project takes place from April/May to August.

Recent Individual Research Projects include:

- Separation – from Subsea to Topside
- Evaluation of Multiphase Flow Metering
- Multiphase Jet Pumps
- Sand Transport in Undulating Terrains.

Modules

The taught programme for the Flow Assurance masters is generally delivered from October to March and is comprised of eight compulsory modules, and one optional module to select from a choice of four. The modules are delivered over one to two weeks of intensive delivery with the later part of the module being free from structured teaching to allow time for more independent learning and reflection. Students on the part-time programme will complete all of the compulsory modules based on a flexible schedule that will be agreed with the course director.

Assessment

Taught modules: 40%; Group project: 20% (dissertation for part-time students); Individual Research Project: 40%.
The taught modules are assessed by an examination and/or assignment. The Group Project is assessed by a written technical report and oral presentations. The Individual Research Project is assessed by a written thesis and oral presentation.

Funding

Bursaries are available; please contact the Course Director for more information.

Cranfield Postgraduate Loan Scheme (CPLS) - https://www.cranfield.ac.uk/Study/Postgraduate-degrees/Fees-and-funding/Funding-opportunities/cpls/Cranfield-Postgraduate-Loan-Scheme

The Cranfield Postgraduate Loan Scheme (CPLS) is a funding programme providing affordable tuition fee and maintenance loans for full-time UK/EU students studying technology-based MSc courses.

Career opportunities

There is considerable global demand in the oil and gas industry for flow assurance specialists with in-depth technical knowledge and practical skills. The industry led education makes our graduates some of the most desirable for recruitment in this sector. The depth and breadth of the course equips graduates with knowledge and skills to tackle one of the most demanding challenges to secure our energy resource. Graduates of the course can also be recruited in other upstream and downstream positions. Their knowledge can additionally be applied to the petrochemical, process and power industries.

Further Information

For further information on this course, please visit our course webpage - http://www.cranfield.ac.uk/courses/masters/flow-assurance-for-oil-and-gas-production.html

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This programme integrates important, current and employer relevant themes and enables you to acquire knowledge and skills across a wide range of appropriate topics for petroleum, oil and gas technology, with an emphasis upon management. Read more
This programme integrates important, current and employer relevant themes and enables you to acquire knowledge and skills across a wide range of appropriate topics for petroleum, oil and gas technology, with an emphasis upon management.

This MSc is taught by lectures, practical experiments and design projects, supported by problem classes and tutorials. Laboratory-based work is an important part of the programme and takes a number of forms, from experimental investigation carried out individually over a short period of time, to extended group project work in which teamwork, project management and communication skills are as important as technical proficiency.

Core modules

• Energy Technologies
• Engineering Management for Process Industries
• Industrial Management, Research Skills and Project Planning
• Sustainable Business: Principles and Practice of Green Management
• Petroleum and Petrochemical Engineering
• Petroleum, Oil and Gas: Chemical Engineering Management MSc Project

Optional modules

• Advanced Process Simulation and Modelling Techniques
• Qualitative/Quantitative Research in Business and Management

The focus on technology, its applications, uses and refinements, are novel features of this programme.

Our campus is ideally situated in the Humber region, which is home to more than 350 companies involved in the chemical and allied industries including ConocoPhillips, BP Chemicals, Total, Reckitt Benckiser and Smith and Nephew.

As a student on the MSc, you will gain access to some of the best facilities in the UK including the Centre for Assessment of Technical Competency (CATCH). This £8 million centre provides a fantastic opportunity to experience realistic equipment and operating procedures.

We work closely with industry to ensure the standard of our teaching keeps pace with advances in the profession. For this reason, our engineering graduates are highly soughtafter by all employment sectors.

The School’s continued development of chemical engineering-related provision has the support of the chemical and process engineering’s professional body, the IChemE.

Research areas

The School focuses on the application of research to solve real-world problems by taking a multi-disciplinary approach. Specialist research activities in a broad range of chemical engineering topics are currently being undertaken and include: process simulation; energy utilisation; carbon capture and sequestration; oil and gas engineering; heat transfer and fluid dynamics.

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Designed in close collaboration with industry, this programme takes a theoretical and a practical approach to ensure it meets the requirements of potential employers. Read more
Designed in close collaboration with industry, this programme takes a theoretical and a practical approach to ensure it meets the requirements of potential employers.

The interdisciplinary nature of the MSc makes it suitable for applicants from a wide variety of engineering and scientific backgrounds. It is appropriate for you if you wish to enter, or enhance, a technical career in the petroleum, oil and gas industry.

This MSc is studied full-time over one year starting in September and comprises two semesters of taught modules followed by an individual research project.

This programme integrates important, current and employer relevant themes and enables students to acquire knowledge and skills across a wide range of appropriate topics for petroleum, oil and gas technology, with an emphasis upon chemical engineering applications.

This MSc is taught by lectures, practical experiments and design projects, supported by problem classes and tutorials. Laboratory-based work is an important part of the programme and takes a number of forms, from experimental investigation carried out individually in a short period of time, to extended group project work in which teamwork, project management and communication skills are as important as technical proficiency.

Core modules

• Energy Technologies
• Advanced Process Safety and Control
• Industrial Management, Research Skills and Project Planning
• Advanced Process Simulation and Modelling Techniques
• Petroleum and Petrochemical Engineering
• Chemometrics for Engineers
• Petroleum, Oil and Gas: Chemical Engineering Technologies MSc Project

The focus on technology, its applications, uses and refinements, are novel features of this programme.

Our campus is ideally situated in the Humber region, which is home to more than 350 companies involved in the chemical and allied industries including ConocoPhillips, BP Chemicals, Total, Reckitt Benckiser and Smith and Nephew.

As a student on the MSc, you will gain access to some of the best facilities in the UK including the Centre for Assessment of Technical Competency (CATCH). This £8 million centre provides a fantastic opportunity to experience realistic equipment and operating procedures.

We work closely with industry to ensure the standard of our teaching keeps pace with advances in the profession. For this reason, our engineering graduates are highly soughtafter by all employment sectors.

The School’s continued development of chemical engineering-related provision has the support of the chemical and process engineering’s professional body, the IChemE.

Research areas

The School focuses on the application of research to solve real-world problems by taking a multi-disciplinary approach. Specialist research activities in a broad range of chemical engineering topics are currently being undertaken and include: process simulation; energy utilisation; carbon capture and sequestration; oil and gas engineering; heat transfer and fluid dynamics.

Read less
This course blends biochemical engineering with business management to prepare you for a career in biopharmaceuticals or industrial biotechnology. Read more

About the course

This course blends biochemical engineering with business management to prepare you for a career in biopharmaceuticals or industrial biotechnology. We also cover:

Industrial applications
Industry-relevant applications of engineering analysis
Working in teams
Independent working and learning

The bioscience industries have a huge role to play in the search for sustainable energy, food production and medicine. They need managers who understand the science, the technology and the business. Our MSc is designed to produce graduates who are up to the challenge.

Take advantage of our expertise

Our teaching is grounded in specialist research expertise. Our reputation for innovation secures funding from industry,
UK research councils, the government and the EU. Industry partners, large and small, benefit from our groundbreaking work addressing global challenges.

You’ll have access to top facilities, including modern social spaces, purpose-built labs, the Harpur Hill Research Station for large-scale work, extensive computing facilities and a modern applied science library. There are high-quality research facilities for sustainable energy processes, safety and risk engineering, carbon capture and utilisation, and biological processes and biomanufacturing.

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