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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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Whether you’re from an engineering, scientific or technical background, this programme will equip you with expertise in new and traditional energy technologies, renewable energy sources, solid waste recycling, air pollution, climate change and energy management systems. Read more

Whether you’re from an engineering, scientific or technical background, this programme will equip you with expertise in new and traditional energy technologies, renewable energy sources, solid waste recycling, air pollution, climate change and energy management systems.

You’ll gain an understanding of the environmental impacts of energy technology choices and the technical expertise to further develop them, preparing you to handle the complex challenges created by the growing energy demands, climate change and urban growth of the 21st century.

Core modules will build your knowledge of topics like atmospheric pollution controls, as well as a range of renewable technologies. You’ll also choose from optional modules that suit your interests and career plans such as combustion theory, energy management or fuel processing.

Specialist facilities

You’ll benefit from the chance to study in cutting-edge facilities where our researchers are pushing the boundaries of sustainable energy engineering. We have a wide range of analytical facilities for advanced fuel characterisation, environmental monitoring and pollution control.

There are also pilot scale combustion systems, and wide range of experimental facilities researching the production of low carbon fuels and energy from waste and new materials such as biomass and algae. In our Energy Building, you’ll even find a full scale engine testing and transport emissions suite, and pilot scale wave power, fuel cell, gas turbine power station, wind and solar labs and rigs.

Accreditation

The course is accredited by the Energy Institute (EI) under licence from the UK regulator, the Engineering Council, which adheres to the requirements of further learning for Chartered Engineer (CEng) status. 

Course content

Core modules will develop your understanding of key topics such as how air pollution and carbon emissions can be measured and controlled, as well as their impact on the surrounding environment. You’ll also focus on renewable technologies such as wind, solar and geothermal energy and hydroelectricity.

In addition, you’ll consider waste and biomass as renewable technologies and how energy can be recovered from landfill and waste incineration. You’ll also gain a broader understanding of the contexts in which these technologies are emerging, including related legal, environmental and financial issues.

With this foundation, you’ll specialise in areas that suit your interests and career ambitions when you choose from optional modules. You could focus on energy management and conservation, or how developments in engine technology are making transportation more fuel efficient, among other topics.

In the latter part of the year, you’ll focus on your research project. You’ll choose your topic – normally related to one of our world-class research institutes – and work closely with your supervisor to apply what you’ve learned to a real-life problem.

Want to find out more about your modules?

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

Course structure

Compulsory modules

  • Research Project (MSc) 60 credits
  • Pollution Sampling and Analysis 15 credits
  • Renewable Technologies 30 credits
  • Atmospheric Pollution: Impacts and Controls 30 credits
  • Advanced Renewable Technologies 15 credits

Optional modules

  • Combustion Theory and Design 15 credits
  • Energy Management and Conservation 15 credits
  • Fuel Processing 15 credits
  • Advanced Engines and Turbines 15 credits

For more information on typical modules, read Energy and Environment 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.

Recent research projects by students on this programme have included:

  • Potential of marine biomass for production of chemicals and biofuels
  • Influence of particle size on the analytical and chemical properties of Miscanthus energy crop
  • Assessing the exposure of commuters to traffic generated particles:
  • a comparison of transport options
  • Location of solar farms under climate change
  • Steam reforming of waste pyrolysis oils for sustainable hydrogen production

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 need for all businesses and industrial companies to reduce their greenhouse gas emissions will be a major driver of future development. Graduates with the skills offered by this course will be in high demand.

Typically, graduates are likely to go on to work in senior posts with high levels of responsibility in energy and environmental consultancies, energy specialists, architectural firms, environmental departments of local authorities, government agencies, major funding bodies, large industrial companies and emerging businesses in the renewable sector.

You’ll also be well prepared for PhD level study and a career in academic research.



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Created in the context of the rapid advancement of the renewable-energy industry, this Masters programme investigates both renewable energy and systems technologies. Read more

Created in the context of the rapid advancement of the renewable-energy industry, this Masters programme investigates both renewable energy and systems technologies.

It is designed to build your competence and confidence in the R&D and engineering tasks that are demanded of scientific engineers in the renewable and sustainable-development sector.

Programme structure

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Facilities, equipment and academic support

Modules related to the different groups are taught by a total of six full-time members of staff and a number of visiting lecturers.

As part of their learning experience, students have at their disposal a wide range of relevant software needed to support the programme material dissertation projects. In recent years, this work included the design of various knowledge-based and business systems on the internet, the application of optimisation algorithms, and semantic web applications.

Numerous laboratory facilities across the Faculty and the University are also available for those opting for technology-based projects, such as the process engineering facility, a control and robotics facility and signal processing labs.

The work related to the MSc dissertation can often be carried out in parallel with, and in support of, ongoing research. In the past, several graduates have carried on their MSc research to a PhD programme.

Career prospects

Engineers and scientists are increasingly expected to have skills in information systems engineering and decision-support systems alongside their main technical and/or scientific expertise.

Graduates of this programme will be well prepared to help technology-intensive organisations make important decisions in view of vast amounts of information by adopting, combining, implementing and executing the right technologies.

Educational aims of the programme

This programme investigates both renewable energy and systems technologies in order to produce scientific researchers and engineers who are competent in the R&D and engineering tasks applicable to the renewable energy and sustainable development sectors.

Its primary aims lie in developing a global understanding of the major types of renewable energy technologies, in-depth knowledge of the technology for biomass-based renewable energy, and knowledge and skills in systems modelling and optimisation.

A balanced curriculum will be provided with a core of renewable energy and systems engineering modules supplemented by a flexible element by way of elective modules that permit students to pursue an element of specialisation relevant to their backgrounds, interests and/or career aspirations.

An integrated approach is taken so as to provide a coherent view that explores the interrelationships between the various components of the programme.

Programme learning outcomes

Knowledge and understanding

The programme aims to develop the knowledge and understanding in both renewable energy and systems engineering. The key learning outcomes include:

  • State-of- the-art knowledge in renewable energy technologies, in terms of: the sources, technologies, systems, performance, and applications of all the major types of renewable energy; approaches to the assessment of renewable energy technologies; the processes, equipment, products, and integration opportunities of biomass-based manufacturing
  • State-of- the-art knowledge in process systems engineering methods, in the areas of: modelling and simulation of process systems; mathematical optimization and decision making; process systems design
  • Advanced level of understanding in technical topics of preference, in one or more of the following aspects: process and energy integration, economics of the energy sector, sustainable development, supply chain management

Intellectual / cognitive skills

The programme aims to strengthen cognitive skills of the students, particularly in the aspects of problem definition, knowledge and information acquiring, synthesis, and creativity, as collectively demonstrable through the successful completion of the research dissertation. The key learning outcomes include the abilities to:

  • Select, define and focus upon an issue at an appropriate level
  • Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
  • Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills

The programme primarily aims to develop skills for applying appropriate methods to analyze, develop, and assess renewable technologies and systems. The key learning outcomes include the abilities to:

  • Assess the available renewable energy systems
  • Design and select appropriate collection and storage, and optimise and evaluate system design
  • Apply generic systems engineering methods such as modelling, simulation, and optimization to facilitate the assessment and development of renewable energy technologies and systems

Key / transferable skills

The programme aims to strengthen a range of transferable skills which are relevant to the needs of existing and future professionals in knowledge intensive industries irrespective of their sector of operation. The key learning outcomes include the further development of the skills in the following areas:

  • Preparation and delivery of communication and presentation
  • Report and essay writing
  • Use of general and professional computing tools
  • Collaborative working with team members
  • Organizing and planning of work
  • Research into new areas, particularly in the aspect of literature review and skills acquisition

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.



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The European Masters in Renewable Energy is a collaborative programme offered by 9 leading European universities. This programme teaches students about the latest advances in clean power developments. Read more
The European Masters in Renewable Energy is a collaborative programme offered by 9 leading European universities.

This programme teaches students about the latest advances in clean power developments. The MSc enables graduates to design and develop benign renewable energy technologies that can be implemented in countries around the world to reduce our fossil fuel emissions.

Core study areas include solar power, wind power, water power, biomass, sustainability and energy systems, subject specialisation at a second university and a major individual research project internship in a renewable energy company.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/european-masters-renewable-energy/

Programme modules

Core Semester – studied at Loughborough University:
- Solar Power
- Wind Power
- Water Power
- Biomass
- Sustainability and Energy Systems Specialisation

Module taken with a European partner university:
- Renewable technology six month project undertaken in a company or research centre

Project:
- Six month project undertaken in a company or research centre

How you will learn

The European Masters in Renewable Energy is composed of three sections. It begins with a core first semester that presents modules in Solar Power, Wind Power, Biomass Energy and Water Power.

For the second semester students move to a second university to specialize in the subject shown below. Finally, a major individual research project internship in a renewable energy company is carried out in the final six months of the Master’s degree.

Careers and further study

Due to the unique nature of the programme not only do students develop technical and scientific competencies in renewable energy, they also develop soft skills such as flexibility, adaptability, team spirit, and the ability to work in a multicultural environment, which are essential when working in an expanding global renewable energy market.

Why choose electronic, electrical and systems engineering at Loughborough?

We develop and nurture the world’s top engineering talent to meet the challenges of an increasingly complex world. All of our Masters programmes are accredited by one or more of the following professional bodies: the IET, IMechE, InstMC, Royal Aeronautical Society and the Energy Institute.

We carefully integrate our research and education programmes in order to support the technical and commercial needs of society and to extend the boundaries of current knowledge.

Consequently, our graduates are highly sought after by industry and commerce worldwide, and our programmes are consistently ranked as excellent in student surveys, including the National Student Survey, and independent assessments.

- Facilities
Our facilities are flexible and serve to enable our research and teaching as well as modest preproduction testing for industry.
Our extensive laboratories allow you the opportunity to gain crucial practical skills and experience in some of the latest electrical and electronic experimental facilities and using industry standard software.

- Research
We are passionate about our research and continually strive to strengthen and stimulate our portfolio. We have traditionally built our expertise around the themes of communications, energy and systems, critical areas where technology and engineering impact on modern life.

- Career prospects
90% of our graduates were in employment and/or further study six months after graduating. They go on to work with companies such as Accenture, BAE Systems, E.ON, ESB International, Hewlett Packard, Mitsubishi, Renewable Energy Systems Ltd, Rolls Royce and Siemens AG.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/european-masters-renewable-energy/

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This Masters programme trains graduates of engineering, science or related disciplines in general and specialist process systems engineering subjects. Read more

This Masters programme trains graduates of engineering, science or related disciplines in general and specialist process systems engineering subjects.

Such areas are not generally covered in engineering and science curricula, and BSc graduates tend to be ill prepared for the systems challenges they will face in industry or academia on graduation.

Programme structure

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Facilities, equipment and academic support

Modules related to the different groups are taught by a total of six full-time members of staff and a number of visiting lecturers.

As part of their learning experience, students have at their disposal a wide range of relevant software needed to support the programme material dissertation projects. In recent years, this work included the design of various knowledge-based and business systems on the internet, the application of optimisation algorithms, and semantic web applications.

Numerous laboratory facilities across the Faculty and the University are also available for those opting for technology-based projects, such as the process engineering facility, a control and robotics facility and signal processing labs.

The work related to the MSc dissertation can often be carried out in parallel with, and in support of, ongoing research. In the past, several graduates have carried on their MSc research to a PhD programme.

Career prospects

Engineers and scientists are increasingly expected to have skills in information systems engineering and decision-support systems alongside their main technical and/or scientific expertise.

Graduates of this programme will be well prepared to help technology-intensive organisations make important decisions in view of vast amounts of information by adopting, combining, implementing and executing the right technologies.

Educational aims of the programme

The programme aims to provide a highly vocational education which is intellectually rigorous and up-to-date. It also aims to provide the students with the necessary skills required for a successful career in the process industries.

This is achieved through a balanced curriculum with a core of process systems engineering modules supplemented by a flexible element by way of elective modules that permit students to pursue an element of specialisation relevant to their backgrounds, interests and/or career aspirations.

An integrated approach is taken so as to provide a coherent view that explores the interrelationships between the various components of the programme. The programme draws on the stimulus of the Faculty’s research activities.

The programme provides the students with the basis for developing their own approach to learning and personal development.

Programme learning outcomes

Knowledge and understanding

  • State-of- the-art knowledge in process systems engineering methods, in the areas of: modelling and simulation of process systems, mathematical optimization and decision making, process systems design, supply chain management, process and energy integration, and advanced process control technologies
  • Advanced level of understanding in technical topics of preference, in one or more of the following aspects: renewable energy technologies, refinery and petrochemical processes, biomass processing technologies, and knowledge-based systems

Intellectual / cognitive skills

The programme aims to strengthen cognitive skills of the students, particularly in the aspects of problem definition, knowledge and information acquiring, synthesis, and creativity, as collectively demonstrable through the successful completion of the research dissertation. The key learning outcomes include the abilities to:

  • Select, define and focus upon an issue at an appropriate level
  • Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
  • Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills

The programme primarily aims to develop skills for applying appropriate methods to analyse, develop, and assess process systems and technologies. The key learning outcomes include the abilities to:

  • Assess the available systems in the process industries
  • Design and/or select appropriate system components, and optimise and evaluate system design
  • Apply generic systems engineering methods such as modelling, simulation, and optimization to facilitate the assessment and development of advanced process technologies and systems

Key / transferable skills

The programme aims to strengthen a range of transferable skills which are relevant to the needs of existing and future professionals in knowledge intensive industries irrespective of their sector of operation. The key learning outcomes include the further development of the skills in the following areas:

  • Preparation and delivery of communication and presentation
  • Report and essay writing
  • Use of general and professional computing tools
  • Collaborative working with team members
  • Organising and planning of work
  • Research into new areas, particularly in the aspect of literature review and skills acquisition

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.



Read less
This MSc teaches an international community of students about the latest advances in clean power developments and enables graduates to design and develop benign renewable energy solutions that can be implemented in countries around the world. Read more
This MSc teaches an international community of students about the latest advances in clean power developments and enables graduates to design and develop benign renewable energy solutions that can be implemented in countries around the world.

It is aimed at engineers and natural scientists pursuing or wishing to pursue a career in the renewable energy sector, particularly those in technical positions e.g. systems designers, technical consultants and R&D engineers and scientists.

Core study areas include solar power, wind power, water power, biomass, sustainability and energy systems, integration of renewables and a research project.

Optional study areas include advanced solar thermal, advanced photovoltaics, advanced wind, energy storage, energy system investment and risk management.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/renewable-energy-systems-tech/

Programme modules

Compulsory Modules:
- Solar Power
- Wind Power 1
- Water Power
- Biomass
- Sustainability and Energy Systems
- Integration of Renewables
- Research Project

Optional Modules (choose three):
- Advanced Solar Thermal
- Advanced Photovoltaics
- Wind Power 2
- Energy Storage
- Energy System Investment and Risk Management

How will you learn

You can select options to develop a chosen specialism in greater depth, including through your individual project which is often carried out with renewable energy companies or alongside the research portfolio of our international experts.

This is a very practical course backed up by strong theoretical understanding of the principles and facts behind renewable energy production.

Assessment is via a mixture of written and practical coursework and examinations. The individual research project is also assessed by viva. Because of its multidisciplinary nature, assessment may be done in collaboration with academic colleagues from Civil Engineering, Mechanical Engineering and Materials.

Facilities

We have current industrial equipment and laboratories for PV cell production, PV module production, qualification testing, PV quality control, energy storage research facilities, vacuum glazing, wind flow measurement, and instrumentation for energy consumption and monitoring.

You will benefit from experience with industrial tools and software for system design (e.g. PV Syst, WASP, ReSoft Windfarm, DNV GL Windfarmer), materials research hardware (e.g. pilot lines for commercial solar cell production) and quality control laboratories.

This enables you to acquire the practical skills that industry uses today and builds the foundations for developing your knowledge base throughout their career.

Careers and further study

There is a world-wide shortage of skilled engineers in this field and so the combination of hands on experience with global industry standard tools and techniques and the strong theoretical knowledge which graduates of this course acquire, makes them highly attractive to employers.

Students may carry out their projects as part of a short-term placement in a company and graduates of this course are often fast-tracked in their applications. Consequently we have an extensive network of alumni, many in top jobs.

Why choose electronic, electrical and systems engineering at Loughborough?

We develop and nurture the world’s top engineering talent to meet the challenges of an increasingly complex world. All of our Masters programmes are accredited by one or more of the following professional bodies: the IET, IMechE, InstMC, Royal Aeronautical Society and the Energy Institute.

We carefully integrate our research and education programmes in order to support the technical and commercial needs of society and to extend the boundaries of current knowledge.

Consequently, our graduates are highly sought after by industry and commerce worldwide, and our programmes are consistently ranked as excellent in student surveys, including the National Student Survey, and independent assessments.

- Facilities
Our facilities are flexible and serve to enable our research and teaching as well as modest preproduction testing for industry.
Our extensive laboratories allow you the opportunity to gain crucial practical skills and experience in some of the latest electrical and electronic experimental facilities and using industry standard software.

- Research
We are passionate about our research and continually strive to strengthen and stimulate our portfolio. We have traditionally built our expertise around the themes of communications, energy and systems, critical areas where technology and engineering impact on modern life.

- Career prospects
90% of our graduates were in employment and/or further study six months after graduating. They go on to work with companies such as Accenture, BAE Systems, E.ON, ESB International, Hewlett Packard, Mitsubishi, Renewable Energy Systems Ltd, Rolls Royce and Siemens AG.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/renewable-energy-systems-tech/

Read less
Climate change is a major challenge for the 21st century, requiring an alternative supply of cleaner energy from renewable sources. Read more
Climate change is a major challenge for the 21st century, requiring an alternative supply of cleaner energy from renewable sources. This course is designed with an engineering focus that deals with applications, combined with the business element; applicable whether you work for a large organisation or a small to medium-size enterprise.

The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng(Hons) accredited for CEng, will be able to show that they have satisfied the educational base for CEng registration.

Key features
-The programme provides hands-on skills in 3D CAD and solid modelling, FEA and CFD analysis, Polysun and WindPRO simulations using industry-standard software.
-You can undertake a wide range of challenging and interesting sponsored and non-sponsored projects in the specific areas of wind power, solar power, biofuels and fuel-cells-related technologies.
-Excellent career progression and internship with leading renewable companies: around 80% of students who have graduated from this programme have been recruited by the relevant industries as a consultant such as Atkins, Alstom Power, Inditex, Vattenfall, Shell, SGS UK Ltd and many others.
-Completion of this programme would be an ideal progression to PhD level of research studies if you are interested in following an academic or research career in novel areas of renewable energy.

What will you study?

The course provides an in-depth knowledge of renewable energy systems design and development, commercial and technical consultancy and project management within the sustainable engineering environment.

You will gain technical skills in and knowledge of solar power, wind power, biofuel and fuel cell technologies, as well as renewable energy business and management. In addition, you will gain practical skills in up-to-date computer-aided simulation technologies such as Polysun for solar energy applications, WindPRO for wind farm applications and ECLIPSE for biomass applications.

Option modules enable you to specialise in project engineering and management, as well as risk management or engineering design and development. Advanced topics, such as 3D solid modelling, computer-aided product development and simulation, and computational fluid dynamics (CFD) analysis and simulation allow you to gain further practical and theoretical knowledge of analytical software tools used in product design.

Assessment

Coursework, exams, individual project.

Work placement scheme

Kingston University has set up a scheme that allows postgraduate students in the Faculty of Science, Engineering and Computing to include a work placement element in their course starting from September 2017. The placement scheme is available for both international and home/EU students.

-The work placement, up to 12 months; is optional.
-The work placement takes place after postgraduate students have successfully completed the taught portion of their degree.
-The responsibility for finding the placement is with the student. We cannot guarantee the placement, just the opportunity to undertake it.
-As the work placement is an assessed part of the course for international students, this is covered by a student's tier 4 visa.

Details on how to apply will be confirmed shortly.

Course structure

Please note that this is an indicative list of modules and is not intended as a definitive list.

If you start this course in January, you will complete the same modules as students who started in September but in a different format – please contact us at for more information.

Core modules
-Biomass and Fuel Cell Renewable Technology
-Solar Power Engineering
-Wind Power Engineering
-Project Dissertation

Option modules (choose one)
-Engineering Projects and Risk Management
-Computational Fluid Dynamics for Engineering Applications
-Computer Integrated Product Development

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The two year MSc programme Biosystems Engineering is for students with an (agricultural) engineering background on bachelor level that are interested to pursue a MSc degree in a field where the interaction between technology and biology plays an important role. Read more

MSc Biosystems Engineering

The two year MSc programme Biosystems Engineering is for students with an (agricultural) engineering background on bachelor level that are interested to pursue a MSc degree in a field where the interaction between technology and biology plays an important role.

Programme summary

During the master Biosystems Engineering, students are educated in finding innovative solutions. The programme combines knowledge of technology, living systems, natural and social sciences with integrated thinking using a systems approach. Solutions can be applied to either the field of food or nonfood agricultural production. During the programme, you develop independence and creativity while acquiring skills that enable you to analyse problems and work as part of an interdisciplinary team. Biosystems Engineering is a tailor-made, thesis oriented programme based on the specific interests and competencies of the student.

Thesis tracks

Farm Technology
This topic consists of four main themes, namely automation for bioproduction, greenhouse technology, livestock technology and soil technology. All these topics have the shared goal of designing systems in which technology is applied to the demands of plants, animals, humans and the environment. Examples of such applications include precision agriculture, conservation tillage, fully automated greenhouses and environmentally friendly animal husbandry systems that also promote animal welfare.

Systems and Control
Production processes and various kinds of machinery have to be optimised to run as efficiently as possible; and with the least amount of possible environmental impact. To achieve this, computer models and simulations are developed and improved. Examples include designing control systems for a solar-powered greenhouse to include a closed water cycle and designing a tomato-harvesting robot.

Information Technology
Information and communication play a vital role in our society. It is necessary to acquire, use and store data and information to optimise production processes and quality in production chains. This requires the design and management of business information systems, software engineering, designing databases and modelling and simulation.

Environmental Technology
Environmental technology revolves around closing cycles and reusing waste products and by-products. Processes have to be designed in such a way that they either reuse waste or separate it into distinct and reusable components. Examples include the production of compost, the generation of green energy or the design of environmentally friendly animal husbandry systems and greenhouses.

AgroLogistics
The goals of agrologistics are to get the right product in the right quantity and quality at the right time and to the right place as efficiently as possible while fulfilling the requirements of the stakeholders (such as government legislation and regulations). This requires the design of effective, innovative logistics concepts in agrifood chains and networks. Examples are the design of greenhouses developed for optimal logistics or designing a dairy production process with minimal storage costs.

Biobased Technology
The importance of biobased economy is increasing. Energy savings and the use of renewable energy are directions for achieving an environmentally sustainable industrial society. Biomass of plants, organisms and biomass available can be turned into a spectrum of marketable products and energy. In this track, you learn more about process engineering, biological recycling technology, biorefinery and how to abstract a real system into a physical model and analyse the physical model using dedicated software.

Your future career

Most graduates are employed in the agrofood sector, or related sectors of industry and trade, from local to international companies. They are project leaders, product managers, technical experts, sales specialists or managers at many kinds of companies including designers of agricultural buildings (animal husbandry systems, greenhouses) and bioenergy production systems. Others find jobs with IT companies (climate control computers, automated information systems) or firms in the agro-food chain that produce, store, process, distribute and market agricultural products. In the service sector or at governments, graduates enter careers as consultants, information officers or policymakers in the fields of technology and sustainable agricultural production, while others enter research careers at institutes or universities.

Alumnus Patrick Honcoop.
"I am working as a product manager at 365 FarmNet in Germany. 365FarmNet supports farmers to manage their whole agrarian holding with just one software application. I am responsible for the content of the software. I am the link between the farmers, the agrarian holdings and the software developers. I really enjoy these dynamics and variety within my function. Just like during my studies, when we visited farmers, companies and fairs during courses and excursions organised by the study association."

Related programmes:
MSc Animal Sciences
MSc Plant Sciences
MSc Geo-information Science
MSc Geographical Information Management and Applications
MSc Organic Agriculture

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Your programme of study. Renewable energy engineering is in high demand globally as we find alternate methods of energy harvesting to meet our future energy needs and future proof our reliance on hydrocarbons as much as it is possible to do. Read more

Your programme of study

Renewable energy engineering is in high demand globally as we find alternate methods of energy harvesting to meet our future energy needs and future proof our reliance on hydrocarbons as much as it is possible to do. Considerable innovation and improvements are continuous within this field as it is by no means at a stage where society can rely on it to fuel all needs. The sector is interdisciplinary and this programme provides you with a wide range of very useful skills and knowledge to problem solve and progress current renewables and work towards innovation whether that is in a renewables company or as a start up.

You study electrical and electronic engineering pertinent to smart grid, sensing energy use, developing energy harvesting techniques, and renewable energy exchange, plus ability to harvest energy from all of our natural resources including wind, solar, hydro, marine, geothermal, biomass and other newly developing areas.Renewables is definitely an employable sector as governments are now challenged by finite resources coming from traditional areas, climate change and societal concerns about how we harvest energy in the future and our ability to survive climatic issues, population increase and manage work and life.

Courses listed for the programme

Semester 1

Electrical Systems for Renewable Energy

Renewable Energy 1 (Solar and Geothermal)

Renewable Energy 2 (Biomass)

Fundamental Concepts in Safety Engineering

Semester 2

Renewable Energy 3 (Wind, Marine and Hydro)

Energy Conversion and Storage

Renewable Energy Integration to Grid

Legislation, Planning and Economics

Semester 3

Project

Find out more detail by visiting the programme web page

https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/278/renewable-energy-engineering/

or online delivery at:

https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/1077/renewable-energy-engineering/

Why study at Aberdeen?

  • You study with industry professionals and industry lead projects to encourage and challenge you in practical application
  • The full supply of energy is covered in the programme from the initial harvesting to the conversion methods required to link to grid
  • You can study your degree at University of Aberdeen or online to fit flexibly with your needs
  • You learn within a lab setting with industry visits and events in a global sector community

Where you study

  • University of Aberdeen
  • 12 Months Full Time
  • September start

• Online option available

International Student Fees 2017/2018

Find out about fees:

https://www.abdn.ac.uk/study/international/tuition-fees-and-living-costs-287.php

*Please be advised that online fees may offer a different structure

Scholarships

View all funding options on our funding database via the programme page

https://www.abdn.ac.uk/study/postgraduate-taught/finance-funding-1599.php

https://www.abdn.ac.uk/funding/

Living in Aberdeen

Find out more about:

  • Your Accommodation
  • Campus Facilities
  • Aberdeen City
  • Student Support
  • Clubs and Societies

Find out more about living in Aberdeen:

https://abdn.ac.uk/study/student-life

Living costs

https://www.abdn.ac.uk/study/international/finance.php



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Renewable energy is an essential and vital resource for the world’s future, and future there is an urgent need for engineers capable of solving the industry’s complex challenges in this field. Read more

About the course

Renewable energy is an essential and vital resource for the world’s future, and future there is an urgent need for engineers capable of solving the industry’s complex challenges in this field.

Studying Renewable Energy Engineering at Brunel provides graduates with the knowledge and skills to make a strategic real-world impact in the resolution of the world’s energy problems.

Graduates from Brunel’s MSc in Renewable Energy Engineering will develop:

- The versatility and depth to deal with new, demanding and unusual challenges across a range of renewable energy issues, drawing on an understanding of all aspects of renewable energy principles including economic assessment.

- The imagination, initiative and creativity to enable them to follow a successful engineering career with national and international companies and organisations.

- Specialist knowledge and transferable skills for successful careers including, where appropriate, progression to Chartered Engineer status.

Aims

Huge business incentives, markets and a wide variety of employment opportunities throughout the world are expected with the development of renewable energy resources as a substitute for fossil fuel technology.

The purpose of the MSc programme is to help meet this demand by cultivating qualified and skilled professionals with specialist knowledge in relevant technologies within the renewable energy sector.

The primary aim is to create Master’s degree graduates with qualities and transferable skills ready for demanding employment in the renewable energy sector. These graduates will have the independent learning ability required for continuing professional development and acquiring new skills at the highest level, and the programme also establishes a strong foundation for those who expect to continue onto a PhD or industrial research and development.

Initial programme learning outcomes

The programme will provide opportunities for students to develop and demonstrate knowledge and understanding, qualities, skills and other attributes in the following areas:

Knowledge and understanding of:

1.The principles and environmental impact of renewable energy technologies, including solar (thermal and electricity), wind, tidal, wave and hydro, geothermal, biomass and hydrogen.
3. The principles of energy conversion and appropriate thermodynamic machines.
4. The heat and mass transfer processes that relate to energy systems and equipment.
5. The principles, objectives, regulation, computational methods, economic procedures, emissions trading, operation and economic impact of energy systems.
6. The diversity of renewable energy system interactions and how they can be integrated into actual energy control systems and industrial processes.

At the cognitive thinking level, students will be able to:

1. Select, use and evaluate appropriate investigative techniques.
2. Assemble and critically analyse relevant primary and secondary data.
3. Recognise and assess the problems and critically evaluate solutions to challenges in managing renewable energy projects.
4. Evaluate the environmental and financial sustainability of current and potential renewable energy activities
5. Develop a thesis by establishing the basic principles and following a coherent argument.

In terms of practical, professional and transferable skills, students will be able to:

1. Define and organise a substantial advanced investigation.
2. Select and employ appropriate advanced research methods.
3. Organise technical information into a concise, coherent document.
4. Communicate effectively both orally and in writing.
5. Design and select renewable energy equipment and systems based on specific requirements/conditions.
6. Work as part of, and lead, a team.

Course Content

The taught element of the course (September to April) includes eight modules; delivery will be by a combination of lectures, tutorials and group/seminar work. A further four months (May to September) is spent undertaking the dissertation.

Compulsory modules:

Renewable Energy Technologies I-Solar Thermal and electricity systems
Renewable Energy Technologies II-Wind, Tidal, Wave, Hydroelectricity
Renewable Energy Technologies III-Geothermal, Biomass, Hydrogen
Power Generation from Renewable Energy   
Renewable Energy Systems for the Built Environment
Energy Conversion Technologies
Environmental Legislation: Energy and Environmental Review and Audit
Advanced Heat and Mass Transfer
Dissertation

Teaching

Students are introduced to subject material, including key concepts, information and approaches, through a mixture of standard lectures and seminars, laboratory practical, field work, self-study and individual research reports. Supporting material isavailable online. The aim is to challenge students and inspire them to expand their own knowledge and understanding.

Preparation for work is achieved through the development of 'soft' skills such as communication, planning, management and team work. In addition, guest speakers from industries provide a valuable insight into the real world of renewable energy.

Many of the practical activities in which the students engage, develop into enjoyable experiences. For example, working in teams for laboratory and field work and site visits. We encourage students to develop personal responsibility and contribution throughout the course. Many elements of coursework involve, and reward, the use of initiative and imagination. Some of the projects may be linked with research in CEBER, CAPF and BIPS research centres.

1 Year Full-Time: The taught element of the course (September to April) is delivered by a combination of lectures, tutorials and group/seminar work. From May to September students undertake the dissertation.

3-5 Years Distance Learning: The programme is designed to enable you to conduct most of your studies at home, in your own time and at your own pace. Students are supplied with a study pack in the form of text books and CD-ROMs; cut-off dates for receipt of assignments are specified at the beginning of each stage. Examinations can be taken either at Brunel University London or in the country you are resident in. The dissertation is carried out in one year.

Modules are assessed either by formal examination, written assignments or a combination of the two.

Assessment

Each module is assessed either by formal examination, written assignments or a combination of the two. Cut-off dates for receipt of assignments are specified at the beginning of the academic year. Examinations are normally taken in May. The MSc dissertation project leading to submission of the MSc Dissertation is normally carried out over four months (FT students) or one year (DL students).

Special Features

Excellent facilities
We have extensive and well-equipped laboratories, particular areas of strength being in fluid and biofluid mechanics, IC engines, vibrations, building service engineering, and structural testing. Our computing facilities are diverse and are readily available to all students. The University is fully networked with both Sun workstations and PCs. Advanced software is available for finite and boundary element modelling of structures, finite volume modelling of flows, and for the simulation of varied control systems, flow machines, combustion engines, suspensions, built environment, and other systems of interest to the research groups.

About Mechanical Engineering at Brunel
Mechanical Engineering offers a number of MSc courses all accredited by professional institutes as appropriate additional academic study (further learning) for those seeking to become qualified to register as Chartered Engineers (CEng). Accrediting professional institutes vary by course and include the Institute of Mechanical Engineers (IMechE), Energy Institute (EI) and Chartered Institute of Building Services Engineers (CIBSE).

Teaching in the courses is underpinned by research activities in aerospace engineering, automotive/motorsport engineering, solid and fluid mechanics, and energy & environment. Staff generate numerous publications, conference presentations and patents, and have links with a wide range of institutions both within and outside the UK. The discipline benefits from research collaboration with numerous outside organisations including major oil companies, vehicle manufacturers, and other leading industrial firms and governmental laboratories. We have links with at least six teaching hospitals and work with universities in China, Poland, Egypt, Turkey, Denmark, Japan, Brazil, Germany, Belgium, Greece, Italy and the US.

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

The requirement of UK-SPEC reinforces the need for a recent graduate with a Bachelor degree to take an appropriate postgraduate qualification in order to become a chartered engineer (currently, an accredited Bachelors degree does not enable the graduate to proceed to Chartered Engineer status without additional learning at M level).

This MSc program will be compliant with the further learning requirements of UK-SPEC. Accreditation will be sought from the Institute of Mechanical Engineering (IMechE) and Energy Institute. As a result, it will appeal to recent graduates who have not yet obtained the appropriate qualifications but intend to become Chartered Engineers. Most importantly, it will appeal to Mechanical, Chemical and Building Services Engineering graduates who wish to specialise in energy, or suitably experienced graduates of related subjects such as Physics.

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This is the distance learning version of the full time MSc in Renewable Energy Systems Technology. By using the same course materials distance learning students are able to achieve the same outcomes as the full-time MSc in Renewable Energy Systems Technology. Read more
This is the distance learning version of the full time MSc in Renewable Energy Systems Technology.

By using the same course materials distance learning students are able to achieve the same outcomes as the full-time MSc in Renewable Energy Systems Technology. We have developed new ways of learning, which offer students flexibility in place, pace and mode to meet the demand for this highly sought after qualification but who cannot attend traditional university classes.

By the end of the course, our renewable energy MSc graduates, will have gained a comprehensive understanding of renewable energy technologies and developed a range of important transferable
skills.

Core study areas include solar power, wind power, water power, biomass, sustainability and energy systems, integration of renewables and a research project.

Optional study areas include advanced solar thermal, advanced photovoltaics, energy storage, energy system investment and risk management.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/renewable-energy-system-tech-dl/

Programme modules

Compulsory Modules:
- Sustainability and Energy Systems
- Integration of Renewables
- Solar 1
- Wind 1
- Water Power
- Biomass
- Research Project

Optional Modules (choose three):
- Energy Storage
- Advanced Solar Thermal
- Advanced Photovoltaics
- Wind 2
- Energy System Investment and Risk Management

Normally students are required to obtain 180 Master's level credits in these modules to become a Master of Science in Renewable Energy Systems Technology graduate. However optional leave awards of Postgraduate Diploma (120 credits) or Postgraduate Certificate (60 credits) are possible.

How you will learn

All of our renewable energy MSc Modules consist of a series of Study Units, each covering a specific subject area (see programme modules). Instead of face-to-face lectures and tutorials, the main learning routes for distance learning students are via the University’s virtual learning environment (LEARN). The learning resources for each Study Unit include:
- On line study materials
- Live streamed and recorded lectures
- Virtual and remote laboratories
- Tutorials, assignments and computer aided assessments
- Access to past exam papers

In addition there are several important communication features built into LEARN which include:
- Discussion forums (for communicating with tutors and fellow learners)
- Specialist tutor groups
- Assignment and tutorial upload facility (to allow tutors to check your progress and provide you with feedback)
- Online tutorial sessions with module lectures

Distance learning students also have the option to attend on campus modules.

- Assessment
By examination, coursework, group work and research project. Examinations are held in January and May/June with coursework and group work throughout the programme. The individual MSc research project is assessed by written report and viva voce. Students receive regular feedback on their progress from on-line support officers, tutors and academic staff.

It is also possible for distance learning students to take exams at a suitable local venue either a local British council or a recognised university. For further information about this process please contact the course administrator.

- Technical Requirements
To make full use of distance learning resources, the following are minimum requirements:
- Good specification PC or laptop running the latest operating system
- A printer if you wish to print out materials
- Good computer skills (see below)
- Fast and reliable access to the Internet via Broadband

You will require the skills that allow one to:
- Open, copy, and move files and directories on your hard drive
- Move around the desktop with several applications (programmes) opened at the same time
- Create documents using a software package such as MS Word or similar.
- Be able to zip files and make pdf files
- Manipulate and analyse data using spread sheet software such as MS Excel

Careers and further study

The flexibility offered by this MSc allows graduates already working in or seeking to enter the sector, the opportunity to gain strong technical knowledge whilst continuing to work.This combination of knowledge and practical experience makes them highly attractive to existing and future employers worldwide.

Fees: Structure and scholarships

Unlike the full time course distance learning students pay as they study and will pay for modules prior to registration at the beginning of each semester. There are no additional registration fees.
However please note that distance learning fees are reviewed annually and may increase during your period of study.

Why choose electronic, electrical and systems engineering at Loughborough?

We develop and nurture the world’s top engineering talent to meet the challenges of an increasingly complex world. All of our Masters programmes are accredited by one or more of the following professional bodies: the IET, IMechE, InstMC, Royal Aeronautical Society and the Energy Institute.

We carefully integrate our research and education programmes in order to support the technical and commercial needs of society and to extend the boundaries of current knowledge.

Consequently, our graduates are highly sought after by industry and commerce worldwide, and our programmes are consistently ranked as excellent in student surveys, including the National Student Survey, and independent assessments.

- Facilities
Our facilities are flexible and serve to enable our research and teaching as well as modest preproduction testing for industry.
Our extensive laboratories allow you the opportunity to gain crucial practical skills and experience in some of the latest electrical and electronic experimental facilities and using industry standard software.

- Research
We are passionate about our research and continually strive to strengthen and stimulate our portfolio. We have traditionally built our expertise around the themes of communications, energy and systems, critical areas where technology and engineering impact on modern life.

- Career prospects
90% of our graduates were in employment and/or further study six months after graduating. They go on to work with companies such as Accenture, BAE Systems, E.ON, ESB International, Hewlett Packard, Mitsubishi, Renewable Energy Systems Ltd, Rolls Royce and Siemens AG.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/renewable-energy-system-tech-dl/

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Two-thirds of this programme consist of a research project that enables the student to develop significant expertise in a particular subject. Read more
Two-thirds of this programme consist of a research project that enables the student to develop significant expertise in a particular subject. This is complemented by options from the Department's portfolio of Master's programmes.

The programme is ideal for an industry-based project and/or student. Research can be drawn from across the School's areas of interest and expertise, which include manufacturing systems, control and instrumentation, and bulk solids handling.

Recent research topics include:

- The influence of product temperature upon adhesion to impact zones in process plants

- The design, construction and testing of a test rig to evaluate elutriation segregation; caking problems due to coal-biomass mixes in silos; and approaches for inhibition of cake formation

- The development of a fully automated elutriation tester

- The use of standpipes as a means of allowing the development of full outlet area activation when used in conjunction with preferential flow channel feeders

- A comparison of flow properties of coal, biomass and their mixes using small and large anular shear cells.

Visit the website http://www2.gre.ac.uk/study/courses/pg/res/engresmsc

What you'll study

Strategy and Management (15 credits)
Research Methodology (15 credits)
Research Project and Dissertation (120 credits)
Two options from a range offered by the Department (30 credits)

Fees and finance

Your time at university should be enjoyable and rewarding, and it is important that it is not spoilt by unnecessary financial worries. We recommend that you spend time planning your finances, both before coming to university and while you are here. We can offer advice on living costs and budgeting, as well as on awards, allowances and loans.

Assessment

Students are assessed through examinations, case studies, assignments, practical work and a dissertation.

Career options

Graduates from this programme can pursue opportunities in research and development in their chosen field.

Careers and employability

FACULTY OF ENGINEERING & SCIENCE
We work with employers to ensure our degrees provide students with the skills and knowledge they need to succeed in the world of work. They also provide a range of work experience opportunities for undergraduates in areas such as civil engineering, manufacturing and business information technology.

Find out how to apply here - http://www2.gre.ac.uk/study/apply

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Effective use of renewable energy and improvements in the efficiency of power generation facilities will enable better energy management in the future and help reduce environmental impact. Read more

Why take this course?

Effective use of renewable energy and improvements in the efficiency of power generation facilities will enable better energy management in the future and help reduce environmental impact. This course responds to an urgent need for specialists in energy and power systems management, as well as a growing skills shortage of people with core knowledge in this field.

The course provides relevant, up-to-date skills that will equip both graduates and working professionals in the advanced concepts of sustainable electrical power and energy generation. It offers skills for operation, control, design, regulation and management of power systems and networks of the future. You will also receive training in and understanding of energy production, delivery, consumption and efficiency.

What will I experience?

On this course you will:

Benefit from experts in the industry who will deliver part of the course as visiting lecturers, bringing professional expertise and industry-relevant material
Be encouraged to reach a level of competence and professionalism where you can effectively integrate your technical and non-technical knowledge to solve a range of problems of a complex nature
Learn in a challenging and stimulating study environment
Develop a range of key skills by means of opportunities provided in the study units
Being an MSc course, you are encouraged and expected to be able to reach a level of competence and professionalism where you can effectively integrate your technical and non-technical knowledge to solve a range of problems of a complex nature.

What opportunities might it lead to?

The course will help to maximise your career potential in this field and equips you to work as an engineer, at an advanced level, in the fields of energy and power systems management.

Module Details

You will study several key topics and complete a four-month individual project in which you apply your knowledge to a significant, in-depth piece of analysis or design. Projects are tailored to your individual interests and may take place in our own laboratories or, by agreement, in industry. Experts from Industry (STS Nuclear) deliver part of the course as visiting lecturers, bringing professional expertise and industry-relevant material to the programme.

Here are the units you will study:

Power Systems Technology: This unit provides an in-depth overview of contemporary electrical power systems. It covers the elements of electrical power systems including generation, transmission and distribution in the mixed energy source paradigm.

Electrical Machines and drives: Provides an in-depth overview of the operational principles and physical design of DC and AC electrical machines as well as broad understanding of concepts of power electronics and power electronic converters, so that you can describe their application and selection criteria. You will develop an understanding of the issues present in converter design, including the impact of physical layout and heat dissipation.

Energy Systems: Focuses on the techniques and principles of operation of thermodynamics and combustion systems, as well as the provision and management of energy. It also focuses on power generation and combined systems, BioMass processers application of heat and fluid transfer.

Renewable and Alternative Energy: Provides an in-depth coverage of the principles of renewable and alternative energy systems: Winds, Solar, BioMass, Geothermal, Fuel Cells, Hydrogen Technologies and Nuclear Energy.

Nuclear Technology: A study of nuclear engineering including the theory of atomic and nuclear physics, methods and benefits of generating electricity from nuclear power plants, and the effects of ionising radiation. The nuclear fuel cycle and the associated environmental impacts are also considered. The development of international guidance on nuclear and radiological safety and a comparison of national regulatory structures are analysed. The importance of safety cultures, safety behaviours and safety cases is a key element throughout this module.

Energy Management: The unit is specifically designed to provide the students with the basic of economical analysis and evaluation of energy projects and asset management as well as risk and hazard assessment, comprising legislation, hazard identification and quantification, quantified risk analyses, methods of elimination/mitigation, economic appraisal of integrated renewable, and petroleum projects; with numerous pertinent case studies.

Programme Assessment

You will be taught through a mixture of lectures, seminars, tutorials (personal and academic), laboratory sessions and project work. The course has a strong practical emphasis and you will spend a significant amount of time in our Energy, Power systems and Electronic laboratories.

A range of assessment methods encourages a deeper understanding of engineering and allows you to develop your skills. Here’s how we assess your work:

Written examinations
Coursework
Laboratory-based project work
A major individual project/dissertation

Student Destinations

This course is designed to respond to a growing skills shortage of people with core knowledge in energy and power systems management. It is an excellent preparation for a successful career in this ever expanding and dynamic field.

On successful completion of the course, you will have gained the skills and knowledge that will make you attractive to a wide variety of employers with interests ranging from overall system design to the more detailed development of subsystems. You will acquire the ability to critically evaluate methodologies, analytical procedures and research methods in energy and power systems management and in the use of state-of-the-art computational tools, the design of sustainable electrical power systems and networks and regulatory frameworks. For practicing engineers with professional business experience, the course is an opportunity to update your knowledge of current design practice and also to familiarise themselves with developments in codes and methods of analysis.

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The Biotechnology MSc within the Institute of Biological, Environmental and Rural Sciences (IBERS) provides you with key skills, specialist knowledge and essential training for a career in industrial or academic bioscience. Read more

About the course

The Biotechnology MSc within the Institute of Biological, Environmental and Rural Sciences (IBERS) provides you with key skills, specialist knowledge and essential training for a career in industrial or academic bioscience. Increasingly, biotechnology companies are recruiting Master’s students with specialised skills to perform jobs previously the reserve of Doctorate level scientists.
At the end of the course you will be able to meet the challenges of biotechnology, demonstrate critical thinking and solve problems, exploit opportunities, and know how ideas can be turned into viable businesses or a successful grant application.

Why study Biotechnology at IBERS?

You want specialist experience and knowledge in biotechnology research and commercial application to give you a competitive edge in the job market and underpin your successful career. IBERS has the credentials to deliver these goals.

With 360 members of staff, 1350 undergraduate students and more than 150 postgraduate students IBERS is the largest Institute within Aberystwyth University. Our excellence in teaching was recognised by outstanding scores in the National Student Satisfaction Survey (2016), with three courses recording 100% student satisfaction and a further 10 scoring above the national average. The latest employability data shows that 92% of IBERS graduates were in work or further study six months after leaving Aberystwyth University. The most recent joint submission to the Research Excellence Framework (REF) displayed that 78% of our research as world-leading or internationally excellent, 97% of our research is internationally recognised, and 76% judged as world-leading in terms of research impact.

IBERS is internationally-recognised for research excellence and works to provide solutions to global challenges such as food security, sustainable bioenergy, and the impacts of climate change. IBERS hosts 2 National bioscience facilities: The National Plant Phenomics Centre –a state of the art automated plant growth facility that allows the high throughput evaluation of growth and morphology in defined environments, and the BEACON Centre of Excellence for Biorefining - a £20 million partnership between Aberystwyth, Bangor and Swansea Universities set up to help Welsh businesses develop new ways of converting biomass feedstocks and waste streams into products for the pharmaceutical, chemicals, fuel and cosmetic industries.

IBERS has a track record of working with academic and industrial partners to develop and translate innovative bioscience research into solutions that help mitigate the impacts of climate change, animal and plant disease, and deliver renewable energy and food and water security.

Course structure and content

In the first 2 semesters the course focuses on 2 key areas of biotechnology: industrial fermentation (manufacturing processes, feedstock pretreatment, fermentation, and the biorefining of low cost feedstocks to high value products) and plant biotechnology (synthetic biology, gene editing, precision genome modification, transformation technologies, up and down gene regulation and silencing, and gene stacking). In addition you will receive practical training in state of the art molecular and analytical bioscience techniques and technologies, and learn of marine, food and health biotechnology, and how the sustainable use of bio-resources and bioscience can help meet the needs of the growing human population. All course modules are delivered by academics and professional practitioners at the forefront of activity in the field.

In the final semester you will work on your own research project with your dissertation supervisor. This could be a project of your own design and will focus on an aspect of biotechnology that you found particularly interesting; it may even be something that you want to develop as a business idea in the future. During your dissertation project you will use the knowledge and the skills that you gained during the first 2 semesters. Your dissertation project will give you an opportunity to become an expert in your topic and to develop research skills that will prepare you for your future career in biotechnology. Your tutor will mentor you in hypothesis driven experimental design, train you in analytical techniques e.g. gas and liquid chromatography, mass spectrometry, vibrational spectroscopy, fermentation, product isolation, biomass processing, analysis of complex experimental data, and the formation of robust conclusions. You will also be guided in writing your dissertation.

Core modules:

- Bioconversion and Biorefining
- Frontiers in Biosciences
- Research Methods in the Biosciences
- Current Topics in Biotechnology
- Crop Biotechnology
- Biotechnology for Business
- Dissertation

Employability

There is great demand nationally and internationally for skilled graduates in Biotechnology, indeed the UK Biotechnology and Biological research Council (BBSRC) have made ‘Bioenergy and Biotechnology’ a strategic priority for science funding. The sector is expanding rapidly and provides excellent employment opportunities for biotechnology graduates. A recent report for the British research councils estimated that in the financial year 2013/14, British industrial biotechnology and bioenergy activities involved around 225 companies and generated £2.9billion of sales. The biotechnology industry makes a significant contribution to the United Kingdom’s net exports, equivalent to £1.5 billion and offsetting 4% of the country’s total trade deficit. In this year alone, biotechnology attracted £922 million in investment (4.6% of investment in the UK by the private sector). In the same year the biotechnology industry employed approximately 8,800 jobs in the UK in jobs ranging from scientists, technicians and analytical staff, and an extimated 11,000 additional jobs in UK suppliers and support industries - see http://www.bbsrc.ac.uk/documents/capital-economics-biotech-britain-july-2015/. These figures are typical of international trends and students graduating from the Biotechnology MSc at IBERS will be very well placed to follow a career in the Biotechnology sector.

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Organizations are seeking to create new products and consumers are demanding green alternatives. This has given rise to many opportunities to develop green, sustainable products and chemistries to replace oil-based products and fuels. Read more

Organizations are seeking to create new products and consumers are demanding green alternatives. This has given rise to many opportunities to develop green, sustainable products and chemistries to replace oil-based products and fuels. These include pharmaceuticals, food packaging, clothing and building materials, as well as cutting-edge carbon nanofibers and biofuels. UBC is a world leader in creating innovative value from forest biomass, and graduates of this program will take their place as technical leaders and sector specialists in this growing industry.

The Master of Engineering Leadership (MEL) in Green Bio-Products is an intensive one-year degree program that will equip you with the technical and leadership skills required to contribute to the growing bio-economy. The project-based curriculum covers all stages of the industry value chain. Graduates will gain a comprehensive and integrated understanding of the chemistry and anatomy of the tree and its role as one of the most prolific forms of biomass. While 60 per cent of your classes will focus on your technical specialization, the remaining 40 per cent are leadership development courses that will enhance your business, communication and people skills. Delivery of the management and leadership courses are in partnership with UBC's Sauder School of Business.

What Makes The Program Unique?

The MEL in Green Bio-Products degree was developed in close collaboration with industry partners, who told us they need to hire leaders with cross-functional technical and business skills to develop innovative solutions, manage teams and direct projects.

Students will develop the sector-relevant cross-disciplinary technical skills in demand by top employers. Distinct from other programs in Canada and internationally, the combination of technical expertise and leadership development makes the MEL in Green Bio-Products program unique and highly relevant in today’s business environment.

To complement your academic studies, professional development workshops, delivered by industry leaders, are offered throughout the year-long program. These extra-curricular sessions cover a range of topics such as:

-Leadership fundamentals

-Giving and receiving feedback

-Learning how to deliver a successful pitch

-Effective presenting

The workshops also provide opportunities to network with professionals from a wide range of industries, UBC faculty and students in the MEL and MHLP programs.

Career Options

Our graduates will be in high demand locally, nationally and internationally, equipped to take on challenging roles in this rapidly evolving sector. They will be participating in developing advanced technical processes, product ideation and take on senior management roles. As a graduate of this program, you will have the skills to take your career to the next level – working as an industry leader who is a peer to your engineering team members and confidently managing projects.



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