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Masters Degrees (Energy Modelling)

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Take advantage of one of our 100 Master’s Scholarships to study Power Engineering and Sustainable Energy at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Power Engineering and Sustainable Energy at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The Master's course in Power Engineering and Sustainable Energy places strong emphasis on state-of-the-art semiconductor devices and technologies, advanced power electronics and drives, and advanced power systems. The Power Engineering and Sustainable Energy course also covers conventional and renewable energy generation technologies. Exciting new developments such as wide band gap electronics, energy harvesting, solar cells and biofuels are discussed and recent developments in power electronics are highlighted.

Key Features of MSc in Power Engineering and Sustainable Energy

The College of Engineering has an international reputation for electrical and electronics research for energy and advanced semiconductor materials and devices.

Greenhouse gas emission and, consequently, global warming are threatening the global economy and world as we know it. A non-rational use of electrical energy largely contributes to these.

Sustainable energy generation and utilisation is a vital industry in today’s energy thirsty world. Energy generation and conversion, in the most efficient way possible, is the key to reducing carbon emissions. It is an essential element of novel energy power generation system and future transportation systems. The core of an energy conversion system is the power electronics converter which in one hand ensures the maximum power capture from any energy source and on another hand controls the power quality delivered to grid. Therefore the converter parameters such as efficiency, reliability and costs are directly affecting the performance of an energy system.

Transmission and distribution systems will encounter many challenges in the near future. Decentralisation of generation and storage systems has emerged as a promising solution. Consequently, in the near future, a power grid will no longer be a mono-directional energy flow system but a bi-directional one, requiring a much more complex management.

The MSc in Power Engineering and Sustainable Energy is modular in structure. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation. Power Engineering and Sustainable Energy students must successfully complete Part One before being allowed to progress to Part Two.

Part-time Delivery mode

The part-time scheme is a version of the full-time equivalent MSc in Power Engineering and Sustainable Energy scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option.

Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.

Modules

Modules on the MSc Power Engineering and Sustainable Energy course can vary each year but you could expect to study:

Advanced Power Electronics and Drives
Power Semiconductor Devices
Advanced Power Systems
Energy and Power Engineering Laboratory
Power Generation Systems
Modern Control Systems
Wide Band-Gap Electronics
Environmental Analysis and Legislation
Communication Skills for Research Engineers
Optimisation

Facilities

The new home of MSc in Power Engineering and Sustainable Energy is at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Engineering at Swansea University has extensive IT facilities and provides extensive software licenses and packages to support teaching. In addition the University provides open access IT resources.

Our new WOLFSON Foundation funded Power Electronics and Power System (PEPS) laboratory well-appointed with the state-of the-art equipment supports student research projects.

Careers

Employment in growing renewable energy sector, power electronic and semiconductor sector, electric/hybrid vehicle industry.

The MSc Power Engineering and Sustainable Energy is for graduates who may want to extend their technical knowledge and for professional applicants be provided with fast-track career development. This MSc addresses the skills shortage within the power electronics for renewable energy sector.

Links with industry

BT, Siemens, Plessey, GE Lighting, Schlumberger, Cogsys, Morganite, Newbridge Networks, Alstom, City Technology, BNR Europe, Philips, SWALEC, DERA, BTG, X-Fab, ZETEX Diodes, IQE, IBM, TSMC, IR, Toyota, Hitachi.

As a student on the MSc Power Engineering and Sustainable Energy course, you will learn about numerical simulation techniques and have the opportunity to visit electronics industries with links to Swansea.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

With recent academic appointments strengthening electronics research at the College, the Electronic Systems Design Centre (ESDC) has been re-launched to support these activities.

The Centre aims to represent all major electronics research within the College and to promote the Electrical and Electronics Engineering degree.

Best known for its research in ground-breaking Power IC technology, the key technology for more energy efficient electronics, the Centre is also a world leader in semiconductor device modelling, FEM and compact modelling.

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The importance of well-functioning energy markets to the global economy cannot be exaggerated. As the energy mix employed by countries around the world becomes increasingly diversified, there also arises the need to develop academic curricula designed to educate a new workforce suited to this dynamic sector. Read more

Programme description

The importance of well-functioning energy markets to the global economy cannot be exaggerated. As the energy mix employed by countries around the world becomes increasingly diversified, there also arises the need to develop academic curricula designed to educate a new workforce suited to this dynamic sector.

MSc Energy Finance and Markets applies principles of financial and resource economics to prepare students for careers in old and new energy markets and industries, as well as the public sector.

Although the programme content relates to a wide array of energy sector career paths, the programme is specifically targeted at candidates who are interested in career opportunities in the finance departments of energy utilities, energy/commodity trading desks of financial and energy firms, energy consultancies, as well as relevant public, academic and third sector positions.

The programme incorporates significant input from energy industry and energy commodities trading executives. Students on the programme work with industry partners to develop cutting edge trading and project solutions within consultancy projects sponsored by energy firms and commodity trading desks of financial and oil and gas institutions.

MSc Energy Finance and Markets provides students with a vital understanding of how energy markets work and energy projects are appraised from both policy and financial economics perspectives. This is done through the delivery of a careful selection of academically grounded courses with significant practical elements.

The programme is designed for candidates who desire to pursue careers that require the understanding of the political economy and financial and resource economics issues in the energy industry. It is also suited to those who desire careers in the public sector and further study in the academia.

The courses offered provide strong academic conditioning for the students, but also offer relevant industry-facing applications. Given the importance of industry relevance, the programme regularly hosts key industry stakeholders as guest lecturers and master class leaders. Students are therefore readily exposed to practical application of financial modelling and analytical techniques widely employed in the execution of energy projects, as well as those used for trading execution in the wider energy markets.

Contemporaneous policy issues are also explored in great detail, underscoring the dynamic nature of the programme’s content.

Programme structure

Learning will primarily be through lectures, set reading, class discussions, exercises, group-work assignments, problem solving in tutorials and case studies. Assessment methods include examinations, assignments, presentations or continuous assessment.

Learning outcomes

By the conclusion of the programme, students should be able to:

demonstrate an advanced knowledge of key theoretical finance and economic concepts underpinning the operations in global and regional energy markets
demonstrate knowledge of how key regional and global energy markets (oil, gas, electricity etc) are structured and how they work
have in-depth understanding of the relationships existing among the key global energy markets; for example, how gas prices translate into less demand for coal and other energy commodities
conduct financial appraisal of energy projects within relevant regulatory contexts
trade energy commodities on global and regional markets’ exchanges/trading platforms by using state of the art software packages and harnessing the power of relevant real-time energy industry data
demonstrate an appreciation of the role played by global, regional and national policies in shaping the demand and supply of energy commodities, as well as relevant energy mixes
demonstrate an appreciation of the complex nature of global energy markets, especially the oil and gas markets, which incorporates supply from developing countries with varied market/operational structures

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This programme takes a multi-disciplinary approach to sustainable solutions for future energy needs, with an in-depth knowledge of the new emerging alternative technologies. Read more
This programme takes a multi-disciplinary approach to sustainable solutions for future energy needs, with an in-depth knowledge of the new emerging alternative technologies. It will prepare you for immediate contribution to the renewable energy sector, entering public, environmental, industry and commercial industries.

Why Renewable Energy and Environmental Modelling at Dundee?

Climate change is possibly the most significant threat that humanity has ever faced. A new generation of scientists, engineers and policy-makers will need to be equipped with skills to enable them to make informed decisions on all aspects of this important and rapidly developing subject.

Our Masters degree in Renewable Energy and Environmental Modelling is designed to produce graduates with a broad and balanced skills base.

We provide the opportunity for you to go on field trips and external conferences as a part of your coursework, and you will have the option of undertaking either an industry-based or research-related project.

What's great about this course at Dundee?

The Dundee MSc is intended to interact with the renewables industry on many levels, enabling frequent networking opportunities during the year. The conference-style modules also allow delegates from industry to attend and enhance their skills in an informal and friendly setting. Graduates from this degree will be able to make an immediate contribution to the renewable energy sector.

Dundee University Centre for Renewable Energy (DUCRE)

DUCRE brings together a wide range of scientists with strong interests in renewable energy and evironmental issues. Staff and students in the Centre are engaged in a wide range of diverse renewable energy and environmental research. Projects range from electric vehicle technologies, to wind, solar, and hydro technologies, and from energy policy issues to Third World environmental development analysis.

Who should study this course?

The MSc in Renewable Energy and Environmental Modelling suits students and professionals from diverse backgrounds, including scientists, engineers, environmentalists, and policy-makers.

The programme has been designed to appeal to graduates with first degrees in the physical sciences, engineering, environmental science and related subjects. However, all applications will be assessed on their merits, regardless of background, and any relevant experience will also be taken into consideration.

The start date is September each year, and lasts for 12 months.

How you will be taught

This course utilizes conference-style teaching - delivered in one week intensive bursts.

The taught element will be delivered using a lively mix of lectures, seminars, peer-based problem-solving, practical sessions and site visits.

What you will study

Modules cover environmental physics, law and policy, renewable energy technologies, environmental monitoring, and the hydrogen economy.

You will study/take part in:

Foundation in renewable energy
Energy regulation law and security of supply
Hydrogen economy (incorporating fuel cells)
Physical concepts: A primer in energy, electromagnetism & electronic materials
Renewables technologies: In depth investigation of existing & emerging technologies, supply & demand issues, conservation & architectural issues
Environmental modelling: hydrology, carbon cycling, wind, wave & solar modelling
Field trips
Project

How you will be assessed

Students are assessed on written and practical work, formal presentations and a project dissertation.

Careers

Graduates from this programme will be able to make an immediate contribution to the renewable energy sector and make informed decisions that will have an impact on the development of national programmes to meet future targets.

Each graduate will have a firm grasp of the predominant and emerging technologies, and will be able to set these in context using a range of environmental monitoring techniques.

"The MSc provided a good base to research renewable technologies and understand how they fit into the energy mix and government policy. After graduation, I am now employed as Chief Technical Officer at Scottish Renewables."
David Cameron, class of 2008

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This programme is aimed at anyone interested in learning more about the design and operation of low energy buildings with the added attraction of three modules dedicated to computer modelling of building performance – an essential skill for anyone wishing to work in today’s rapidly changing world of building engineering consultancy. Read more
This programme is aimed at anyone interested in learning more about the design and operation of low energy buildings with the added attraction of three modules dedicated to computer modelling of building performance – an essential skill for anyone wishing to work in today’s rapidly changing world of building engineering consultancy.

Modules are taught by world-leading experts in the field who have designed some of the world’s most innovative low energy buildings. These design experiences provide unique case study material which students find exciting and invaluable for their own research and design work.

The programme is accredited for further learning for CEng and professional membership by CIBSE and the Energy Institute and benefits from its links with the Royal Academy of Engineering Centre of Excellence in Sustainable Building Design.

The course attracts students from all over the world, including countries such as Greece, Iran, China, France, Germany and Colombia. This is attractive to potential employers who often have international offices around the world.

Key Facts

- An outstanding place to study. The School of Civil and Building Engineering is ranked 2nd in the UK for Building in the Times Good University Guide 2015

- Research-led teaching from international experts. 75% of the School’s research was rated as world-leading or internationally excellent in the latest Government Research Excellence Framework.

- The programme is accredited by the two main institutions representing energy and buildings – the Chartered Institution of Building Services Engineers and the Energy Institute. On successful completion of the course, students are deemed to meet the education requirements for both institutions and their applications can be endorsed by course tutors.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/low-carbon-building-design/

Programme modules

- Building Energy Consumption [70% exam, 10 credits]
The aim of this module is for the student to understand the impact that climate, people, equipment selection and design have on energy consumption on a range of building sizes from domestic to large commercial.

- Renewable Energy and Low Carbon Technologies [70% exam, 15 credits]
The aims of this module are for the student to understand the principles of renewable energy and low carbon technologies and their integration into buildings, and to be given a perspective on the potential benefits and applications of these technologies.

- Building Control & Commissioning [70% exam, 10 credits]
The aims of this module are for the student to understand the application of automatic control in energy monitoring and commissioning and to examine the control problems in buildings and develop control strategies that will improve thermal comfort and building energy use.

- Concept Design [0% exam, 15 credits]
The aims of this module are for the student to be introduced to the process within which buildings are conceived and designed by undertaking the architecture design of a major building using multi-disciplinary input. Students will develop team skills through working in design groups to generate schematic concepts before developing the best. They will apply previous knowledge of building services and low carbon design in the selection process and carry out performance analysis. Students will work with 3D architectural and 3D mechanical, electrical and plumbing (MEP) systems within BIM software to further develop their concepts.

- Low Carbon Building Design [50% exam, 15 credits]
The module aims to introduce the principles of low and zero carbon building with special attention to the process of design and decision-making.

- Advanced Thermal Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of building thermal modelling and HVAC plant simulation, and be given a perspective on the applications of these techniques to the design process.

- Advanced Airflow Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of building airflow and ventilation modelling with respect to comfort and energy efficiency, and be given a perspective on the applications of these techniques to the design process.

- Advanced Lighting Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of lighting modelling in buildings with respect to comfort and energy efficiency, and be given a perspective on the application of these techniques to the design process.

- Research Project [0% exam, 60 credits]
The aim of this module is to provide the student with experience of the process and methodology of research by defining and studying (on an individual basis) a complex problem in a specialised area relating to Building Energy

- Research Methods in Building Performance [0% exam, 10 credits]
The aims of this module are for the student to become familiar with and comprehend the wide range of research methods and skills needed to investigate, understand and communicate building performance.

Facilities

All masters students have access to a wide range of building simulation codes which include commercial software, as well as bespoke codes developed in-house. Students can run these codes on their personal laptops or access any one of our computer laboratories, including access to our recently commissioned 2000-node high performance computer cluster.

One of our key strengths at Loughborough is our experimental facilities which enable us to validate computer models. Our masters students have access to a vast range of experimental facilities, some of which are used during the taught modules and all of which are available for use by students during their research dissertations.

These include: a fully controllable environmental chamber; sophisticated thermal and breathing manikins; an indoor solar simulator; a 'darkroom' facility to carry out optical and high dynamic range measurements; and full-scale houses for pressure testing and studying innovative heating and control strategies. A recent investment of £360k was made to purchase an extensive array of monitoring and measuring equipment for use during field studies.

How you will learn

You will learn through a carefully balanced combination of lectures, in-class guided workshops, hands-on computer modelling, field measurements and independent research. Students have access to a wide range of air flow, thermal and daylight modelling software as well as extensive laboratory facilities. Following nine taught modules, students pursue a research dissertation of their choice which draws on the skills developed during the taught modules.

Students are assessed by a combination of traditional written exams, coursework and assignments. This split is typically 70/30 (exam/coursework) or 50/50, although some modules, such as research methods and concept design are assessed entirely based on coursework which comprises individual presentations and group work.

Careers and further study

Previous students have gone on to work for leading consulting engineering companies such as Arup, Pick Everad, Hoare Lea, Hulley and Kirkwood and SE Controls. Some of these companies offer work placements for students to undertake their research dissertations. Many visit the university to deliver lectures to our MSc students providing ideal opportunities for students to discuss employment opportunities.

Accreditation

The programme is accredited for further learning for CEng and professional membership by the CIBSE and Energy Institute.
The 'SE Controls prize for best overall performance' is awarded to the student graduating from this course with the highest overall mark. This presentation is made on graduation day.

Scholarships

The University offers over 100 scholarships each year to new self-financing full-time international students who are permanently resident in a county outside the European Union. These Scholarships are to the value of 25% of the programme tuition fee and that value will be credited to the student’s tuition fee account.
You can apply for a scholarship once you have received an offer for a place on this programme.

Why choose civil engineering at Loughborough?

As one of four Royal Academy of Engineering designated Centres of Excellence in Sustainable Building Design, the School of Civil and Building Engineering is one of the largest of its type in the UK and holds together a thriving community of over 60 academic staff, 40 technical and clerical support staff and over 240 active researchers that include Fellows, Associates, Assistants, Engineers and Doctoral Students.

Our world-class teaching and research are integrated to support the technical and commercial needs of both industry and society. A key part of our ethos is our extensive links with industry resulting in our graduates being extremely sought after by industry and commerce world-wide,

- Postgraduate programmes
The School offers a focussed suite of post graduate programmes aligned to meet the needs of industry and fully accredited by the relevant professional institutions. Consequently, our record of graduate employment is second to none. Our programmes also have a long track record of delivering high quality, research-led education. Indeed, some of our programmes have been responding to the needs of industry and producing high quality graduates for over 40 years.

Currently, our suite of Masters programmes seeks to draw upon our cutting edge research and broad base knowledge of within the areas of contemporary construction management, project management, infrastructure management, building engineering, building modelling, building energy demand and waste and water engineering. The programmes are designed to respond to contemporary issues in the field such as sustainable construction, low carbon building, low energy services, project complexity, socio-technical systems and socio-economic concerns.

- Research
Drawing from our excellent record in attracting research funds (currently standing at over £19M), the focal point of the School is innovative, industry-relevant research. This continues to nurture and refresh our long history of working closely with industrial partners on novel collaborative research and informs our ongoing innovative teaching and extensive enterprise activities. This is further complemented by our outstanding record of doctoral supervision which has provided, on average, a PhD graduate from the School every two weeks.

- Career Prospects
Independent surveys continue to show that industry has the highest regard for our graduates. Over 90% were in employment and/or further study six months after graduating. Recent independent surveys of major employers have also consistently rated the School at the top nationally for civil engineering and construction graduates.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/low-carbon-building-design/

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This programme is idea for graduates from engineering, science or other relevant backgrounds and who have an interest in pursuing a successful career in research, technological change and the commercialisation of renewable-energy systems. Read more
This programme is idea for graduates from engineering, science or other relevant backgrounds and who have an interest in pursuing a successful career in research, technological change and the commercialisation of renewable-energy systems.

This programme will give you opportunities to learn about major renewable-energy technologies, energy-sector economics, supply-chain management and sustainable development.

PROGRAMME OVERVIEW

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. 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.
-Optimisation and Decision-Making
-Process Modelling and Simulation
-Technology, Business & Research Seminars
-Renewable Energy Technologies
-Refinery and Petrochemical Process
-Solar Energy Technology
-Advanced Process Control
-Energy Economics and Technology
-Process Systems Design
-Biomass Processing Technology
-Wind Energy Technology
-Process and Energy Integration
-Knowledge-based Systems and Artificial Intelligence
-Supply Chain Management
-Introduction to Petroleum Production
-Process Safety and Operation Integrity
-Economics of International Oil & Gas
-Dissertation

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
-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
-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
-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
-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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This MSc is unique in the UK in focusing on five core areas which have risen rapidly up the public agenda – environment, climate and energy economics, modelling and policy – and for which there is a need for highly qualified practitioners with the skills to analyse the issues and relate the results to policy. Read more
This MSc is unique in the UK in focusing on five core areas which have risen rapidly up the public agenda – environment, climate and energy economics, modelling and policy – and for which there is a need for highly qualified practitioners with the skills to analyse the issues and relate the results to policy.

Degree information

Students will reach a deep understanding of different economic and policy approaches to the resource and environmental problems facing the global community and nation states, especially in respect to energy and climate change. They will learn how to apply a variety of analytical methods to resolve these problems in a broad range of practical contexts.

Students undertake modules to the value of 180 credits.

The programme consists of five core modules (75 credits), three optional modules (45 credits) and a dissertation (60 credits).

Core modules
-Environmental and Resource Economics
-Evidence, Policy Assessment and Environmental Law
-Modelling, Methods and Scenarios
-Planetary Economics and the Political Economy of Energy and Climate Change
-Research Concepts and Methods

Optional modules
-Advanced Energy-Environment-Economy Modelling
-UK Energy and Environment Policy and Law
-Energy, Technology and Innovation
-Energy, People and Behaviour
-Business and Sustainability
-Advanced Environmental Economics
-Econometrics for Energy and the Environment

The list of optional modules is correct for the 2016-17 academic year. Enrollment on modules is subject to availability.

Dissertation/report
All students undertake an independent research project which culminates in a 10,000-word dissertation.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials and project work. Assessment is through examination, coursework and by dissertation.

Careers

Graduates of this programme will be equipped to become leaders and entrepreneurs in their chosen area of specialisation, whether in terms of policy-making, the business management of sustainable issues, energy system modelling or their understanding and application of innovative systems.

The skills that they will acquire will make them strong applicants for employment in a range of sectors in which sustainability has become an important consideration, including business, central and local government, think tanks and NGOs and universities and research institutes.

Employability
The uniquely interdisciplinary nature of this Master's provides students with practical skills which are highly sought by employers from a variety of fields. Students will have the opportunity to attend networking events, career workshops and exclusive seminars held at the UCL Energy Institute.

Why study this degree at UCL?

The UCL Energy Institute is world leader in a range of areas covered by the programme; for example, energy systems, energy economics, energy and environmental policy and law and behavioural aspects of energy use.

Our sister institute, the UCL Institute of Sustainable Resources, provides additional expertise on resource economics. These areas are increasingly important due to related challenges, such as climate change, resource exhaustion and energy affordability.

There is a definite need for quantitative, practical environment and resource economists who understand policy. The appeal of this MSc is two-fold: it offers those with quantitative first degrees the chance to acquire high-level, energy-environment-economy modelling skills, but in relaxing the level of mathematical skills required, it is also ideal for those with largely non-quantitative first degrees.

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UCC have developed a Masters in Engineering Science in Sustainable Energy, in recognition of the growing international market for sustainable energy systems and the shortage of qualified engineers. Read more
UCC have developed a Masters in Engineering Science in Sustainable Energy, in recognition of the growing international market for sustainable energy systems and the shortage of qualified engineers. This programme is open to Engineering graduates of all disciplines with an 8 month programme option leading to a Postgraduate Diploma in Sustainable Energy.

Visit the website: http://www.ucc.ie/en/ckr26/

Course Details

In Part I students take modules to the value of 50 credits and a Preliminary Research Report in Sustainable Energy (NE6008) to the value of 10 credits. Part II consists of a Dissertation in Sustainable Energy (NE6009) to the value of 30 credits which is completed over the summer months.

Part I

Students take 50 credits as follows:

NE3002 Energy in Buildings (5 credits)
EE3011 Power Electronic Systems (5 credits)
EE4010 Electrical Power Systems (5 credits)
NE3003 Sustainable Energy (5 credits)
NE4006 Energy Systems in Buildings (5 credits)
NE6003 Wind Energy (5 credits)
NE6004 Biomass Energy (5 credits)
NE6005 Ocean Energy (5 credits)
NE6006 Solar and Geothermal Energy (5 credits)
NE6007 Energy Systems Modelling (5 credits)

Depending on the background of the student, the Programme Coordinator may decide to replace some of the above taught modules from the following list of modules up to a maximum of 20 credits:

CE4001 The Engineer in Society (Law, Architecture and Planning) (5 credits)
EE3012 Electromechanical Energy Conversion (5 credits)
EE4001 Power Electronics, Drives and Energy Conversion (5 credits)
EE4002 Control Engineering (5 credits)
EE6107 Advanced Power Electronics and Electric Drives (5 credits)
ME6007 Mechanical Systems (5 credits)
NE4008 Photovoltaic Systems (5 credits)
PE6003 Process Validation and Quality (5 credits)

In addition, all students must take 10 credits as follows:

NE6008 Preliminary Research Report in Sustainable Energy (10 credits)

Part II

NE6009* Dissertation in Sustainable Energy (30 credits)

*must be submitted on a date in September as specified by the Department

Detailed Entry Requirements

Candidates must have a BE(Hons) or BEng (Hons) Degree or equivalent engineering qualification, with a minimum grade 2H2. However, candidates with equivalent academic qualifications and suitable experience may be accepted subject to the approval of College of Science, Engineering and Food Science. In all cases, the course of study for each candidate must be approved by the Programme Coordinator.
Candidates, for whom English is not their primary language, should possess an IELTS of 6.5 (or TOEFL equivalent) with no less than 6.0 in each individual category.

Candidates from Grandes Écoles Colleges are also eligible to apply if they are studying a cognate discipline in an ENSEA or EFREI Graduate School and are eligible to enter the final year (M2) of their programme.

Assessment

- Postgraduate Diploma in Sustainable Energy -

Students who pass but fail to achieve the requisite grade of 50% across the taught modules and the Preliminary Research Report will be eligible for the award of a Postgraduate Diploma in Sustainable Energy. Candidates passing Part I of the programme who do not wish to proceed to Part II may opt to be conferred with a Postgraduate Diploma in Sustainable Energy.

How to apply: http://www.ucc.ie/en/study/postgrad/how/

Funding and Scholarships

Information regarding funding and available scholarships can be found here: https://www.ucc.ie/en/cblgradschool/current/fundingandfinance/fundingscholarships/

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The MRes in Energy Demand Studies is designed to equip students for careers as professional researchers. Technical work is highly topical, focusing on energy demand in the built environment, and is complemented by the development of research and transferable skills. Read more
The MRes in Energy Demand Studies is designed to equip students for careers as professional researchers. Technical work is highly topical, focusing on energy demand in the built environment, and is complemented by the development of research and transferable skills.

Degree information

The programme focuses on skills and knowledge required to undertake research in energy demand reduction in the built environment and comprises three strands: technical modules, transferable skills and research. Topics include thermodynamics, building physics, behaviour, energy systems, modelling, policy and economics. Transferable skills include writing, presenting and communicating with different stakeholders. Significant emphasis is placed on research and methodologies.

Students undertake modules to the value of 180 credits. The programme consists of four technical modules (two valued at 15 credits each, two audited), two transferable skills modules (15 credits each), a guided research project (30 credits) and a dissertation research project (90 credits).

Technical modules
-Energy Theory, Measurement and Interpretation
-Energy: Society, Economics and Policy
-Energy Demand in Context

Transferable skills modules
-Research Concepts
-Communication Skills

Dissertation/report
All students undertake a guided team research project, and an independent research project which culminates in a dissertation of 15,000 words.

Teaching and learning
Teaching sessions are highly interactive and led by experienced researchers. Students read key texts in advance of lectures and seminars to accelerate learning and focus sessions on research-oriented issues. Small group sizes, regular tutorials and supervision meetings combine to provide tailored support across a range of disciplines and research topics.

Placement
All students will attend a residential block week in Loughborough at the London-Loughborough Centre for Doctoral Research in Energy Demand at the start of term one. This will incur no additional costs for students.

Careers

The Energy Demand Studies MRes programme has been developed by experienced researchers to provide a superb grounding in the skills and knowledge required to pursue a research career in a range of sectors such as academia, government, consultancies, engineering companies and NGOs. To date, many of our students have gone on to gain funded PhD studentships at UCL-Energy and multinational organisations such as Parsons Brinckerhoff.

Top career destinations for this degree
-Teaching assistant on Undergraduate and MSc course at UCL, UCL (University College London) and studying MPhil/PhD Energy Demand Reduction and the Built Environment, University College London (UCL)
-PhD Built Environment, University College London (UCL)
-PhD Energy Demand in the Built Environment, University College London (UCL)
-PhD Energy Demand Studies, University College London (UCL)

Employability
Having undertaken a significant original research project, our graduates are well equipped to apply their skills to a career in a research environment. Their technical knowledge combined with transferable skills, such as communication skills, project management and problem solving, are highly sought after in a wide range of careers. Our students gain access to networking events, career workshops and exclusive seminars held at the UCL Energy Institute.

Why study this degree at UCL?

The UCL Energy Institute is a leading centre for research into energy demand and the built environment, a sector of increasing importance due to the challenges of climate change, energy affordability and energy security. Students undertaking the Energy Demand Studies MRes have the opportunity to undertake original research in a multidisciplinary environment and engage with top class researchers.

Research into demand and the built environment provides many challenges for researchers due to the complex interplay of people, buildings and economics. The unique multidisciplinary approach of the programme helps students develop into more complete individual researchers and effectively integrate into research teams.

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Gain the theoretical and practical skills to explore the growing field of renewable energy technologies. Renewable energy technologies have become an important part of energy production. Read more
Gain the theoretical and practical skills to explore the growing field of renewable energy technologies.

Renewable energy technologies have become an important part of energy production. Strong initiatives and investments from the public and private sectors have made this a rapidly growing field and created further career opportunities in the sector.

This is one of the few courses offered at Masters level which not only encompasses renewable energy technologies but also complements with the essential related elements of renewable energy finance and environmental law.

These elements touch on financial analytical tools, project structuring, finance and management in renewable energy, while the law element will consider legal framework impacting upon renewable energy provision.

See the website http://www.napier.ac.uk/en/Courses/MSc-Renewable-Energy-Postgraduate-FullTime

What you'll learn

The course will extend your skills into various renewable energy technologies such as wind, solar, hydro, biomass, wave etc.

Study renewable energy capture, energy storage, energy audit and life-cycle analysis, as well as learning the concept of the system, design, development and applications.

The course is accredited by the Energy Institute, UK. Combined with a suitable accredited undergraduate degree, the MSc degree would then satisfy the academic requirements of the UK Engineering Council for Chartered Engineer (CEng) status.

Modules

• Sustainable energy technologies
• Solar energy: technology, modelling and analysis
• Renewable energy finance and environmental law
• Research skills and project management
• Distributed generation systems
• MSc Project module

Module choice of
• Control engineering
• Energy materials
• Mechatronic systems
• Sustainable urban property development

Study modules mentioned above are indicative only. Some changes may occur between now and the time that you study.

Career opportunities

• Consultancies
• Renewable energy industries
• Renewable energy technology/design
• Building services
• Research & development

How to apply

http://www.napier.ac.uk/study-with-us/postgraduate/how-to-apply

SAAS Funding

Nothing should get in the way of furthering your education. Student Awards Agency Scotland (SAAS) awards funding for postgraduate courses, and could provide the help you need to continue your studies. Find out more: http://www.napier.ac.uk/study-with-us/postgraduate/fees-and-funding/saas-funded-courses

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Costs. Fees for 2016/17 TBC. 2015-2016 Irish/EU €8,500. Plus subsistence expenses (food etc.) associated with field trips, including the Tidal Energy module based at Queen’s Marine Laboratory, Portaferry, Northern Ireland. Read more
Costs: Fees for 2016/17 TBC. 2015-2016 Irish/EU €8,500. Plus subsistence expenses (food etc.) associated with field trips, including the Tidal Energy module based at Queen’s Marine Laboratory, Portaferry, Northern Ireland. Software necessary for assignments will be provided in UCC laboratories but may not be available for remote use. Optional sea safety training.

Overview

The programme covers a range of engineering and non-engineering topics relevant to the marine renewable energy industry, which is expected to grow rapidly in the coming decade. This will lead to a requirement for engineers with good knowledge of engineering fundamentals as well as detailed knowledge of how wind, wave and tidal devices will be designed, deployed and operated. A key aspect of the programme is the provision of specially-developed advanced modules in marine renewable energy which are not available in any other master’s course. This is an all-Ireland programme, hosted by UCC, delivered in partnership with the following academic institutions: Cork Institute of Technology, Dublin Institute of Technology, National University of Ireland, Maynooth, Queen’s University Belfast, University College Dublin and the University of Limerick.

Course Details

Students take 90 credits as follows:

In Part I students must take the five core modules (unless these or equivalent courses have already been taken), to a total of 25 credits. Students also choose electives from the list below, or may, with the approval of the Programme Director, choose other modules from the University’s Calendar.

NB: For the purposes of this programme it has been agreed that all non-UCC modules are treated as either 5 or 10 credits.

Part II consists of a Marine Renewable Energy Research Project (NE6020), to the value of 30 credits, completed over the summer months, either in industry or in an academic research laboratory in one of the partner institutions. Projects are offered subject to availability of suitable proposals from industry, and will be offered to students based on order of merit of results achieved in Part I. Students are also encouraged to make efforts to secure their own placement from suitable industrial hosts, outside of the list provided.

In every case, the final choice of modules is subject to the approval of the Programme Director of the MEngSc (Marine Renewable Energy). Students may take a maximum total of 15 credits only of undergraduate modules on this programme.

Part I
Core Modules
CE4020 Environmental Hydrodynamics (5 credits; UCC)
NE6003 Wind Energy (5 credits; UCC)
NE6005 Ocean Energy (5 credits; UCC)
NE6010 Advanced Topics in Marine Renewable Energy (5 credits; All institutions)
NE6906 Tidal Energy (5 credits; QUB; 1-week block)

Elective Modules

Students select modules to the value of 35 credits from the following list, (or from elsewhere in the UCC Calendar, subject to approval):

AC6301 Innovation Finance (5 credits) (UCC)
NE3003 Sustainable Energy (5 credits; UCC)
CE4013 Harbour & Coastal Engineering (5 credits; UCC)
CE6024 Finite Element Analysis (5 credits; UCC)
EE4001 Power Electronics, Drives & Energy Conversion (5 credits; UCC)
EE4010 Electrical Power Systems (5 credits; UCC)
EV4012 Environmental Impact Assessments (5 credits) (UCC)
GL6007 Practical Offshore Geological Exploration (5 credits; offered subject to availability of survey vessel time) (UCC)
IS6306 Technology Business Planning (5 credits) (UCC)
LW6104 Intellectual Property Law for High-Tech Entrepreneurs (5 credits) (UCC)
NE6007 Energy Systems Modelling (5 credits; UCC)
NE6901 Control Systems (5 credits; NUIM - EE612)
NE6902 Maintenance & Reliability (5 credits; CIT - MANU8003)

Part II
NE6020 Marine Renewable Energy Research Project (30 credits; All institutions; Summer)

Application Procedure

Application for this programme is on-line at http://www.pac.ie/ucc. Places on this programme are offered in rounds. The closing dates for each round can be found here (http://www.ucc.ie/en/study/postgrad/how/applicationclosingdates/). For full details of the application procedure click How to apply - http://www.ucc.ie/en/study/postgrad/how/

Course Practicalities

You will be studying a range of engineering and non-engineering topics relevant to a career in the marine renewable energy industry.

The programme will include modules in engineering topics such as Wind Energy, Wave Energy, Tidal Energy, Ocean-Structure Interactions; Ocean Energy Device Design; Control Engineering; Mechanical Engineering; Grid Integration and Storage; Marine Operations & Robotics.

The course content will be delivered via blended learning, with some modules presented in traditional lecture format, and some modules delivered remotely using e-learning technologies. All modules will have a significant element of continuous assessment throughout the year. The Tidal Energy module is delivered during a one-week field visit to the Portaferry research laboratory of Queen’s University Belfast.

A significant element of the programme is a R&D project carried out in conjunction with either an industry partner or an academic research group, with the final three months spent working on the project on placement with the partner.

Non-engineering topics available include Intellectual Property Law; Innovation Finance; Environmental Impact Assessment; Practical Offshore Geological Exploration.

Assessment

Taught modules (total >= 60 ECTS): will be assessed via a mixture of continuous assessment (assignments and mini design projects) and traditional examinations. This depends on the contributing institution, for example in NUIM, coursework and project-based learning is emphasised. The project module (30 ECTS) will be assessed by means of: oral presentation and seminar; logbook; written report, with input from the industrial placement supervisor.

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Renewable energy is a cornerstone of the green economy and marine wind, wave and tidal energy are key elements of the UK, European and global renewable energy roadmaps. Read more
Renewable energy is a cornerstone of the green economy and marine wind, wave and tidal energy are key elements of the UK, European and global renewable energy roadmaps. Begin your voyage to being a part of this vital transformation by studying on the UK’s first MSc Marine Renewable Energy programme. Building on our international reputation for marine research and teaching along with regional and national initiatives, this distinctive degree focuses on the growing marine renewable energy sector.

Key features

-Be at the forefront of the emerging field of marine renewable energy at a time when such expertise is increasingly sought after.
-Develop knowledge and confidence in the critical areas which will help you to be an integral part of the effort to develop and promote marine renewable energy.
-Benefit from our research team’s expertise – our staff achieved ratings of ‘world leading’ and ‘internationally excellent’ in the UK Government’s most recent Research Excellence Framework (REF 2014).
-Take advantage of Plymouth University’s active role in the Southwest Marine Energy Park and the Offshore Renewables Development Programme to stay abreast of the latest developments and make contacts with key players in the field.
-Gain experience in the use of world leading facilities such as the COAST Lab test tanks and the Falcon Spirit research vessel as part of your taught programme and your research.
-Learn in an environment which benefits from PRIMaRE investment in new staff expertise and facilities.
-Benefit from a programme fully-integrated with the £42 million wave hub project, the world's largest wave energy test site, off north Cornwall.
-Live and study in ‘Britain’s Ocean City’, with easy access to businesses and the natural environment involved in your area of study this is an ideal location to study marine renewables.
-Take the opportunity to study abroad in the research project phase and be supported by one Plymouth University supervisor and one supervisor overseas.

Course details

The taught modules in the first period are compulsory and are designed to provide you with a broad background on marine renewable as well as a solid basis for the option modules in period two. You’ll undertake three modules in period one that provide a background in marine renewable energy: introduction to marine renewable energy, economics, law and policy for marine renewable energy, research skills and research methods. In period two you can choose three options from a choice of five: assessment of coastal resources and impacts, marine planning, economics of the marine environment, mechanics of marine renewable energy structures, and wave and current modelling for marine renewable energy. During period three you’ll undertake a research project and dissertation. Due to the extensive staff research expertise there is a wide range of potential projects spanning marine science, engineering and socio-economics. You may also carry out projects with external organisations that have interests in marine renewable energy.

Core modules
-MAR513 Research Skills and Methods
-MAR526 Introduction to Marine Renewable Energy
-MAR527 Economics, Law and Policy for Marine Renewable Energy
-MAR524 MSc Dissertation

Optional modules
-MAR529 Marine Planning
-MATH523 Modelling Coastal Processes
-MAR528 Mechanics of MRE Structures
-MAR507 Economics of the Marine Environment
-MAR512 Assessment of Coastal Resources and Impacts

Every postgraduate taught course has a detailed programme specification document describing the programme aims, the programme structure, the teaching and learning methods, the learning outcomes and the rules of assessment.

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This programme is aimed at graduates of building services engineering and other science and engineering disciplines who wish to extend their technical expertise in the field of building services engineering. Read more
This programme is aimed at graduates of building services engineering and other science and engineering disciplines who wish to extend their technical expertise in the field of building services engineering. With energy consumption within the design and operation of buildings becoming an ever increasingly important factor this programme is designed to combine building services engineering knowledge with specific energy considerations in their design.

The programme is accredited for further learning for CEng and professional membership by the Energy Institute and CIBSE. CIBSE has praised the programme as ‘one of the leading MSc courses of its kind in the UK’.

Areas studied include low energy building design, designing for suitable indoor air quality and thermal comfort, state-of-the-art control systems, and the design of building heating, ventilating, and air conditioning systems.

The course attracts students from all over the world, including countries such as Greece, Iran, China, France, Germany and Colombia. This is attractive to potential employers who often have international offices around the world.

Key Facts

- An outstanding place to study. The School of Civil and Building Engineering is ranked 2nd in the UK for Building in the Times Good University Guide 2015
- Research-led teaching from international experts. 75% of the School’s research was rated as world-leading or internationally excellent in the latest Government Research Excellence Framework.
- The programme is accredited by the two main institutions representing energy and buildings – the Chartered Institution of Building Services Engineers and the Energy Institute. On successful completion of the course, students are deemed to meet the education requirements for both institutions and their applications can be endorsed by course tutors.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/low-energy-building-services/

Programme modules

Compulsory Modules:
- Thermodynamics, Heat Transfer & Fluid Flow [70% exam, 10 credits]
The aim of this module is to provide students from related engineering backgrounds with an understanding of the fundamentals of heat transfer, fluid flow and thermodynamics for application to buildings and their engineering systems.

- Thermal Comfort & Indoor Air Quality [70% exam, 15 credits]
The aim of this module is for the student to understand the principles and practice involved in the design of indoor environments, with respect to occupant thermal comfort and air quality.

- Building Thermal Loads & Systems [70% exam, 15 credits]
The aim of this module is for the student to understand the principles of building thermal load analysis and required systems for medium to large buildings.

- Building Energy Supply Systems [70% exam, 15 credits]
The aim of this module is for the student to be provided with a practical foundation in system design and analysis, by developing the students' understanding of thermal plant in buildings including air conditioning systems and systems for heat recovery.

- Building Control & Commissioning [70% exam, 10 credits]
The aims of this module are for the student to understand the application of automatic control in energy monitoring and commissioning and to examine the control problems in buildings and develop control strategies that will improve thermal comfort and building energy use.

- Concept Design [0% exam, 15 credits]
The aims of this module are for the student to be introduced to the process within which buildings are conceived and designed by undertaking the architecture design of a major building using multi-disciplinary input. Students will develop team skills through working in design groups to generate schematic concepts before developing the best. They will apply previous knowledge of building services and low carbon design in the selection process and carry out performance analysis. Students will work with 3D architectural and 3D mechanical, electrical and plumbing (MEP) systems within BIM software to further develop their concepts.

- Low Carbon Building Design [50% exam, 15 credits]
The module aims to introduce the principles of low and zero carbon building with special attention to the process of design and decision-making.

- Advanced Thermal Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of building thermal modelling and HVAC plant simulation, and be given a perspective on the applications of these techniques to the design process.

- Research Project [0% exam, 60 credits]
The aim of this module is to provide the student with experience of the process and methodology of research by defining and studying (on an individual basis) a complex problem in a specialised area relating to Building Energy

- Research Methods in Building Performance [0% exam, 10 credits]
The aims of this module are for the student to become familiar with and comprehend the wide range of research methods and skills needed to investigate, understand and communicate building performance.

Facilities

All masters students have access to a wide range of building simulation codes which include commercial software, as well as bespoke codes developed in-house. Students can run these codes on their personal laptops or access any one of our computer laboratories, including access to our recently commissioned 2000-node high performance computer cluster.

One of our key strengths at Loughborough is our experimental facilities which enable us to validate computer models. Our masters students have access to a vast range of experimental facilities, some of which are used during the taught modules and all of which are available for use by students during their research dissertations.

These include: a fully controllable environmental chamber; sophisticated thermal and breathing manikins; an indoor solar simulator; a 'darkroom' facility to carry out optical and high dynamic range measurements; and full-scale houses for pressure testing and studying innovative heating and control strategies. A recent investment of £360k was made to purchase an extensive array of monitoring and measuring equipment for use during field studies.

How you will learn

You will learn through a carefully balanced combination of lectures, in-class guided workshops, hands-on computer modelling, field measurements and independent research. Students have access to a wide range of air flow and thermal modelling software as wells as extensive laboratory facilities. Following nine taught modules, students pursue a research dissertation of their choice which draws on the skills developed during the taught modules.

Students are assessed by a combination of traditional written exams, coursework and assignments. This split is typically 70/30 (exam/coursework) or 50/50, although some modules, such as research methods and concept design are assessed entirely based on coursework which comprises individual presentations and group work.

Careers and further study

Previous students have gone on to work for leading consulting engineering companies such as Arup, Pick Everad, Hoare Lea, Cundall, Foster & Partners, and Atkins. Some of these companies offer work placements for students to undertake their research dissertations. Many visit the university to deliver lectures to our MSc students providing ideal opportunities for students to discuss employment opportunities.

Scholarships

The University offers over 100 scholarships each year to new self-financing full-time international students who are permanently resident in a county outside the European Union. These Scholarships are to the value of 25% of the programme tuition fee and that value will be credited to the student’s tuition fee account.
You can apply for a scholarship once you have received an offer for a place on this programme.

Why choose civil engineering at Loughborough?

As one of four Royal Academy of Engineering designated Centres of Excellence in Sustainable Building Design, the School of Civil and Building Engineering is one of the largest of its type in the UK and holds together a thriving community of over 60 academic staff, 40 technical and clerical support staff and over 240 active researchers that include Fellows, Associates, Assistants, Engineers and Doctoral Students.

Our world-class teaching and research are integrated to support the technical and commercial needs of both industry and society. A key part of our ethos is our extensive links with industry resulting in our graduates being extremely sought after by industry and commerce world-wide,

- Postgraduate programmes
The School offers a focussed suite of post graduate programmes aligned to meet the needs of industry and fully accredited by the relevant professional institutions. Consequently, our record of graduate employment is second to none. Our programmes also have a long track record of delivering high quality, research-led education. Indeed, some of our programmes have been responding to the needs of industry and producing high quality graduates for over 40 years.

Currently, our suite of Masters programmes seeks to draw upon our cutting edge research and broad base knowledge of within the areas of contemporary construction management, project management, infrastructure management, building engineering, building modelling, building energy demand and waste and water engineering. The programmes are designed to respond to contemporary issues in the field such as sustainable construction, low carbon building, low energy services, project complexity, socio-technical systems and socio-economic concerns.

- Research
Drawing from our excellent record in attracting research funds (currently standing at over £19M), the focal point of the School is innovative, industry-relevant research. This continues to nurture and refresh our long history of working closely with industrial partners on novel collaborative research and informs our ongoing innovative teaching and extensive enterprise activities. This is further complemented by our outstanding record of doctoral supervision which has provided, on average, a PhD graduate from the School every two weeks.

- Career Prospects
Independent surveys continue to show that industry has the highest regard for our graduates. Over 90% were in employment and/or further study six months after graduating. Recent independent surveys of major employers have also consistently rated the School at the top nationally for civil engineering and construction graduates.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/low-energy-building-services/

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The built environment is changing - the EU has set a target for all new buildings to be nearly zero-energy efficient by the end of 2020. Read more
The built environment is changing - the EU has set a target for all new buildings to be nearly zero-energy efficient by the end of 2020. This is your opportunity to get up to speed on the newest practices in designing energy efficient buildings and refurbishments.

Through case studies and fieldwork, you will analyse the latest energy efficiency innovations and renewable technologies applied to new buildings and those undergoing a retrofits. By examining contemporary passive houses, nearly-zero buildings and energy plus structures, you'll discover how the leading exemplars in this field achieve their efficiency performances. You'll also study the shortcomings in current building efficiencies - where they fall short in meeting their energy targets and how they can be improved with the resources available.

Your work will be shaped by cutting-edge research as you collaborate with specialists who help inform new Government regulations and policies. This will broaden your knowledge and help you forge contacts with the principal thinkers and leaders in the building performance sector.

Visit the website http://courses.leedsbeckett.ac.uk/energyefficientbuildings_apd

Mature Applicants

Our University welcomes applications from mature applicants who demonstrate academic potential. We usually require some evidence of recent academic study, for example completion of an access course, however recent relevant work experience may also be considered. Please note that for some of our professional courses all applicants will need to meet the specified entry criteria and in these cases work experience cannot be considered in lieu.

If you wish to apply through this route you should refer to our University Recognition of Prior Learning policy that is available on our website (http://www.leedsbeckett.ac.uk/studenthub/recognition-of-prior-learning.htm).

Please note that all applicants to our University are required to meet our standard English language requirement of GCSE grade C or equivalent, variations to this will be listed on the individual course entry requirements.

Careers

Energy efficiency surveyors and specialists arealready in high demand, and the need for their expertise will continue to growas the industry faces tighter energy legislation. This demand should filterthrough to related professions in architecture, construction management andquantity surveying, where knowledge in this area will complement existingexpertise and give those at the start of their careers a significant advantagein the jobs market.

- Property Developer
- Architect
- Construction Manager
- Quantity Surveyor

Careers advice:
The dedicated Jobs and Careers team offers expert advice and a host of resources to help you choose and gain employment. Whether you're in your first or final year, you can speak to members of staff from our Careers Office who can offer you advice from writing a CV to searching for jobs.

Visit the careers site - https://www.leedsbeckett.ac.uk/employability/jobs-careers-support.htm

Course Benefits

You will take part in site visits to study the very latest energy efficient buildings in detail, examining their characteristics and design specifications first-hand.

Our University has strong research links to industry, including many of the organisations such as the Department of Energy and Climate Change and the International Energy Institute that drive the energy efficiency agenda forward. This will give you the chance to network with the leading thinkers sharing and share in their latest insights. You will also evaluate industry software and the methodologies used to assess and monitor building efficiency.

All of our teaching staff have practical experience as consultants in new builds and refurbishment. They are recognised nationally and internationally, and some are directly involved in regulation and research that influences the direction of the industry.

Your course will give you the commanding expertise to make you highly sought after as the industry responds to the growing demand for energy efficiency specialists.

Core Modules

Low to Zero Energy Buildings & Energy Efficient Building Systems
Gain a comprehensive understanding of the principals of low to zero energy buildings, focusing on their energy sustainability, fabric and systems such as lighting and heating.

Sustainable Refurbishment & Retrofit
Discover the techniques relating to sustainable refurbishment and retrofit, examining the design and detail of existing and pre-1900 structures.

Chris Gorse

Senior Lecturer

"New legislation is pushing for tightened building energy requirements over the next few years, so knowledge in this area is essential. Once the legislation is in place, the industry will have to rapidly upskill itself."

Chris Gorse is Professor of Construction and Project Management and Director of Leeds Sustainability Institute. He leads projects in the areas of sustainability, low carbon and building performance and has an interest in domestic new builds, commercial buildings and refurbishment. Chris is an established author and has consultancy experience in construction management and law.

Facilities

- Design Studios
You will be able to access our extensive studio facilities, which include workshops and computer modelling software to design and build projects.

- Library
Our Library is open 24/7, every day of the year. However you like to work, we have got you covered with group and silent study areas, extensive e-learning resources and PC suites.

- Leeds Sustainability Institute
We offer the latest drone and thermal imaging technology to provide new ways of measuring and evaluating building sustainability.

- Broadcasting Place
Broadcasting Place provides students with creative and contemporary learning environments, is packed with the latest technology and is a focal point for new and innovative thinking in the city.

Find out how to apply here - http://www.leedsbeckett.ac.uk/postgraduate/how-to-apply/

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Global warming and fossil fuel depletion increasingly place the development of sustainable energy systems at the top of political agendas around the world. Read more
Global warming and fossil fuel depletion increasingly place the development of sustainable energy systems at the top of political agendas around the world. Major investments in new energy technologies and systems to improve energy efficiency and reduce greenhouse gas emissions will continue to grow the coming decades.

To meet this challenge this master’s programme provides a state of the art education lectured by world-leading researchers and industry professionals in combination with access to unique research facilities.

By acquiring deep technical knowledge in the main energy technologies and by understanding how they interact with economics and energy policies, our graduates become experts in identifying sustainable solutions to complex problems in the energy field.

Programme description

The future will most likely mainly be powered by renewable energy sources like hydropower, bioenergy, solar energy and wind power, but in the process of getting there; society needs a bridge between the technologies of today and the ones of the future.

At Chalmers, we are experts in the bridging technologies and systems that will characterize the professional careers of energy engineers in the coming decades.

Besides analysing the present and expected future energy systems and technologies, the programme covers the transition between them. With this, we offer world-leading education in technologies for clean and efficient heat and power generation, Carbon Capture and Storage (such as chemical looping and oxyfuel combustion), optimization and CO2 mitigation of chemical and industrial processes, efficient energy use in buildings, smart power grids for wind and solar power integration and bioenergy. At a system level, we specialize in energy systems modelling and planning and in environmental impact analysis of the energy sector trough life cycle analysis, ecological risk and environmental assessments.

Energy, is one of Chalmers Areas of Advance and tops the budget list for Chalmers strategic research and educational plan. Our faculty consists of world-renowned researchers like Christian Azar, Lina Bertling and Simon Harvey.

This unique, hands-on and state-of-the-art education in the area of advanced energy technologies and systems provides you with the proficiency needed to undertake energy engineering tasks that assess both technical, environmental and financial aspects.

You will be able to not only master current energy systems and technologies but also get a close insight to the ones of the future.

Educational methods

As we strive for a balance between individual and group assignments, you will take part in lectures, projects, case studies, problem-solving sessions, laboratories and seminars, providing you with an opportunity to train in team-work as well as both written and oral communication and presentation skills.

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A flexible Masters degree designed to develop a rigorous understanding of different energy technologies, exploring the subject through a combination of academic study, discussion and hands-on practical work. Read more

Masters in Renewable Technologies

A flexible Masters degree designed to develop a rigorous understanding of different energy technologies, exploring the subject through a combination of academic study, discussion and hands-on practical work.

How is the course taught?

Taught at the Centre for Alternative Technology (CAT), which pioneered sustainability practice and theory in the UK, the MSc course examines renewable energy provision, increased energy efficiency and intelligent management of energy resources. These topics are explored within the context of the ecological, social and economic impacts and the policy drivers at international, national and local scales. Our MSc programme is taught either by distance learning or through residential blocks in one of the most innovative environmental buildings in the UK, or via a mixture of the two.

Different energy technologies are examined alongside new advances in energy storage, smart grids and meters. Computer modelling, data collection and analysis give students practical experience in effective energy management. Students can choose modules from a wide range that covers environmental assessment and renewable energy, cities and communities, energy provision, energy in buildings, and politics and economics.
 
We give our MSc students the knowledge, skills and experience needed to develop a career in the environmental sector and make an impact. The programme draws on our expert staff (https://gse.cat.org.uk/index.php/postgraduate-courses/msc-sustainability-in-energy-provision-and-demand-management/sepdm-staff-profiles) and a wide selection of academics and specialist guest lecturers – people who have made exceptional contributions to environmental thinking and action.

What qualification will you receive?

Successful completion of the programme MSc Sustainable Energy Provision and Demand Management at the Centre for Alternative Technology leads to the award of Master of Science (MSc) by UEL (subject to validation by the University of East London).

Modules include

-          Sustainability and Adaptation Concepts and Planning
-          Environmental Politics and Economics
-          Adaptation Transformation Politics and Economics
-          Cities and Communities
-          Energy Flows in Buildings – Parts A and B
-          Energy Provision (Wind)
-          Energy Provision (Solar PV)
-          Energy Provision (Renewable Energy)
-          Building Performance Assessment and Evaluation
-          Built Environment Applied Project or Built Environment Practice Based Project

This course is subject to validation by the University of East London.

Why study at CAT?

Studying at the Centre for Alternative Technology (CAT) is a truly unique experience. For the past 40 years CAT has been at the forefront of the environmental movement, pioneering low-carbon living and renewable technology. At the Graduate School of the Environment (GSE), students benefit from our extensive practical and academic knowledge, graduating with the skills needed to become leading players in the sustainability sector. Find out more about our facilities here: https://gse.cat.org.uk/index.php/postgraduate-courses/msc-sustainability-and-adaptation/sa-site-and-facilities

Hands-on learning

At CAT, hands-on learning takes place side by side with academic study. Residential on-site block learning weeks are taught at the Centre for Alternative Technology (CAT), a truly unique and inspiring learning environment. Nestled in a disused slate quarry on the edge of the Snowdonia National Park, CAT is a living laboratory for paractical, sustainable solutions. It contains some of the most innovative and renowned environmentally conscious buildings in the country, as well as one of the most diverse range of installed renewable technologies, on site water and sewage treatment, sustainably managed woodland and acres of organic gardens.

Flexibility

It is a flexible degree, taught in blocks taken either with an intensive residential stay of five or six nights at the centre, or by distance learning. MSc students are free to choose between these teaching modes for every module. There is a choice of modules, taken over one year or two – meaning the degree can be part time. It is a masters degree designed to give you the best possible experience whilst also meshing neatly with the pressures of modern professional and family life.

Immersive learning environment

Optional residential module weeks include lectures, seminars, group work and practicals. Applied work tends to dominate later in the week once we have laid the theoretical groundwork. These module weeks provide a truly immersive environment to escape daily life and apply yourself to new learning. Many eminent experts give guest lectures or hold seminars during these modules, as it is a course which seeks to draw on the expertise and learning of the whole environmental sector.

Is this the course for you?

If you would like to visit for an overnight stay during a module, where you can attend lectures and workshops and meet staff and students, please contact Shereen Soliman:

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