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Discover the real-world career opportunities in the energy sector with this MSc in Energy and Environmental Technology and Economics. Read more
Discover the real-world career opportunities in the energy sector with this MSc in Energy and Environmental Technology and Economics.

Who is it for?

Wherever you are, energy has an implication. This course is for students who want to engage with different types of settings to research and establish the energy, environmental and technological implications that exist within them. Energy and Environmental Technology and Economics students will care for the environment as a sustainable system and ultimately have a desire to improve conditions for the wider population.

Students come from a range of backgrounds including engineering, finance and economics – and from within the energy industry itself.

Objectives

This Masters degree has been designed to give you a wide perspective when it comes to analysing and forecasting the future for energy, environmental technology and economics. We engage with the industry so you gain a real-world understanding of the problems that exist, and we consider our own ethical responsibilities in relation to energy use.

Imagine a Grade 1-listed building such as the Guildhall in London. As an energy consultant your task is to analyse the site to make it more efficient. But there is a caveat: you cannot make any structural changes to the walls or the windows. The MSc Energy and Environmental Technology and Economics course gives you the tools to examine and address these kinds of challenges.

The MSc Energy and Environmental Technology and Economics course is not about learning academic theories. Instead we focus on the breadth of the subject in the real world. By engaging with practising businesses and trade associations we identify a range of perspectives, and look at the influence of a myriad of other forces at play, from regulation and government funding, to behavioural psychology and emerging technologies. Here are some of the questions the course poses:
-Does this new form of technology operate as it should?
-How does the UK relate to other European countries when it comes to energy efficiency?
-How does organisational psychology affect energy use within a company?
-How do you decide which energy contract to choose?
-What is the impact of a consumer society on personal energy use?

Placements

There is no formal requirement to do an industry-based placement as part of the programme. However, some students arrange to undertake their dissertation research within a company or within their part of the world. A recent student investigated the future of coal-fired generation in Turkey, and another student is combining a work placement at The World Energy Council with their dissertation.

Academic facilities

As part of the University of London you can become a member of Senate House Library for free with your student ID card.

Teaching and learning

Teaching is organised into modules comprising four consecutive day courses taken at a rate of one a month or so. This format makes the programme accessible for students who want to study part time while working.

Full-time students are also welcome. Whether you choose to take the course as a part-time or full-time student, we will offer a great deal of support when it comes to helping you prepare for the modules and project work. You will be expected to devote a significant part of your non-taught hours to project work as well as private study.

Our course is led by an exceptional group of experts in energy, supply, demand management and policies. As an example, one of our module leaders leads the UK contribution to writing international energy management standards and informing policy through the European Sector Forum for Energy Management. This forum looks at methodologies across the continent. There is also input to global standards development through the International Standards Organisation (ISO). At City we bring on board people with well-established academic careers as well as leaders from the energy industry. The programme has strong links with industry and commerce and involves many visiting lecturers who hold senior positions in their fields.

The Energy and Environmental Technology and Economics MSc gives you the opportunity to consider the role of International Energy Management Standards. You will explore the opportunities these standards provide for global service users and providers in relation to reducing energy costs and the environmental impact of energy use.

You will discover the range of current European and International Standards, explore why they are needed and how they are developed, and examine the benefits they deliver through case studies.

The UK has had a leading role in developing these standards in terms of both their writing and implementation. For example the Energy Audit standard, which forms part of the EU Energy Efficiency Directive, Article 8, mandates audits for private sector, non-SME organisations. In the UK this has been implemented as the Energy Savings Opportunities Scheme (ESOS).

Modules

Each course module is taught over four consecutive days of teaching with one module each month. Alongside the teaching you will have coursework to complete for each module. The modules run from October to April, and in the remaining time, you will concentrate on your dissertation, which forms a significant part of the programme.

The dissertation gives you the opportunity to create your own questions and to decide on your own area of interest. It should be a detailed investigation into a subject on energy supply and/or demand, with your own analysis and conclusions outlining the way forward. You may see the focus of your dissertation as a future career path, but whatever your area of study, these final few months of the degree should embody your vision of the future.

You will take four core modules and have six elective modules from which you can choose four topics from diverse subjects relating to energy supply and demand. These include energy in industry and the built environment, renewables, energy markets from the purchaser’s perspective and water supply and management. The latter has close parallels, and directly engages, with energy. You start the course with an introduction to energy and environmental issues and energy policies and economic dimensions in the first term, but you do not need to follow the course in any particular order from this point onwards.

If you are interested in sustainability, you have the option of taking up to two elective modules from the MSc in Environmental Strategy offered by the University of Surrey.

Completing eight modules and four examinations and four modular assessments will lead to a Postgraduate Diploma. Completing four core and four elective modules and a dissertation will lead to a Masters degree. If you are interested in this course may also be interested in the MSc Renewable Energy and Power Systems Management.

Core modules
-Introduction to energy and environmental issues (15 credits)
-Energy policies and economic dimensions (15 credits)
-The energy market from the purchaser's perspective (15 credits)
-Corporate energy management (15 credits)

Elective modules
-Energy, consumer goods and the home (15 credits)
-Transport energy and emissions (15 credits)
-Energy in industry and the built environment (15 credits)
-Renewable energy and sustainability (15 credits)
-Risk management (15 credits)
-Water supply and management (15 credits)

Career prospects

The story of energy is now part of public debate and climate change drives the international agenda. In the UK, there are additional energy supply issues, through the decline of existing nuclear capacity, growing imports of fossil fuels and challenging medium-term targets for renewables and low carbon supply.

Our priority is to make you employable in a range of sectors in which effective energy supply and demand side management has become an important consideration.

You will graduate with economic and market-based skills relevant to complying with relevant legislation and technical and engineering skills related to energy generation and management.

With strong industry links and working level experience from our exceptional team of expert lecturers, as well as the diverse modules on offer, you will be equipped to become a leader and entrepreneur in your chosen area of specialisation within the realm of energy management, supply or policy making.

Our graduates have gone on to hold high-ranking positions as energy consultants, data analysts and directors of corporate sustainability working within organisations including:
-AK Home Energy
-Enelco Environmental Technology
-Energy Institute
-Equinoxe Services Ltd
-Log Tech Consultancy
-Ofgem
-Peckham Power
-RWE NPower Renewables
-SCFG

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Intended specifically for students pursuing a career in Architecture, the Professional Diploma course offers a unique combination of design-based academic study and practical hands-on learning. Read more

Part II in Sustainable Architecture

Intended specifically for students pursuing a career in Architecture, the Professional Diploma course offers a unique combination of design-based academic study and practical hands-on learning. The course is prescribed as a Part II qualification by the Architects Registration Board and is recognised by the EU, thereby enabling students to move on to a Part III qualification.

Students are introduced to a range of skills that are increasingly in demand within the building industry. The focus is on designing buildings in their context, to allow for adaptation to the effects of climate change and to create healthy environments for all.

Teaching is delivered in the WISE building - itself an example of recent developments in sustainable construction - and includes a mix of studio- based design work, lectures, seminars and practicals. The annual Summer School enables students to design, detail and build a structure at CAT using the local materials available.

Modules include

- Design studies with professional practice
- Building performance and energy use
- Building performance and the use of materials
- Design and fabrication: renewable energy engineering
- Environment, energy, climate and human beings

What qualification will you receive?

Successful completion of the programme Professional Diploma in Architecture: Advanced Environmental and Energy Sudies at the Centre for Alternative Technology leads to the award of Professional Diploma (ProfDip) by UEL.

Course Structure

The programme runs as eight interlinked modules over a period of eighteen months. The major design project module consists of 60 credits; with two further 30 credit design modules. Each support studies module consists of 30 credits.
The programme is divided into two parts:
Design Studies, forming the core activity
Support Studies, consisting of Environment and Energy Fundamentals, Building Technology in an Environmental Context, History and Theory of Architecture and Professional Studies.

At the beginning of each Module students are given the Module Book which contains lecture notes, reading material, examples of student essays and design work and various items of information and administration. During each module there will be cross disciplinary seminars, workshops and tutorials, as well as specialised design sessions.

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.

Sustainable Architecture taught in Sustainable Building

The Professional Diploma Part 2 course is taught in the Welsh Institute of Sustainable Education (WISE building). This iconic building was named building of the year by the Telegraph in 2010, it also won a internationally recognised RIBA award in 2011. Designed by CAT architects Pat Borer and David Lea, it includes:
a 200-seat circular lecture theatre made from rammed earth
Three large classrooms/workspaces/labs and two further smaller seminar rooms
A computer suite
Foyer with games, books and a bar
24 en-suite twin bedrooms, overlooking a large open roof garden and decking
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.

Practical building and knowledge sharing

Alongside their design and academic work, students of the Professional Diploma in Architecture also participate in a variety of building projects. This allows them to get practical experience and understanding of the complexities of what happens once their designs leave the architectural studio. During these projects architecture students work alongside MSc students who will go into complimentary building professions allowing for networking and a wealth of transferable knowledge.

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.

Creating high standards of Sustainable Architecture

We pride ourselves on the high standard of work that our graduates continue to produce. To see for yourself, have a look at some of the projects our students produce: https://www.flickr.com/photos/catimages/sets/72157649961496950/

Is this the course for you?

If you would like to visit for a free overnight stay during a module, attend lectures and workshops and meet staff and students, please contact the Student Support Officer:

For more information visit: https://gse.cat.org.uk/index.php/postgraduate-courses/professional-diploma-in-architecture-part-ii

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

About the course

Accredited by the Energy Institute and the Institution of Chemical Engineers

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

Take advantage of our expertise

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

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

Studentships

Contact us for current information on available scholarships.

Course content

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

Core modules

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

Examples of optional modules

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

Teaching and assessment

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

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This is a 12 month full-time Masters degree (See http://www.postgraduate.hw.ac.uk/prog/msc-renewable-energy-development-red-/ ) course taught at our Orkney Campus. Read more

Overview

This is a 12 month full-time Masters degree (See http://www.postgraduate.hw.ac.uk/prog/msc-renewable-energy-development-red-/ ) course taught at our Orkney Campus. It involves studying 8 taught courses and completing a research dissertation equivalent to 4 taught courses. If you can demonstrate that you have already mastered the subject, you may apply for an exemption from one of the taught courses and undertake a Design Project instead.

For more information visit http://www.hw.ac.uk/schools/life-sciences/research/icit.htm

Distance learning

The Renewable Energy Development MSc/Diploma is also available for independent distance learning. For distance learners, the main difference is that you will undertake the Development Project alone rather than as part of a group. You can still obtain the full MSc in Renewable Energy Development, or you can opt to study fewer courses, depending on your needs.

Programme content

- Energy in the 21st Century
This course is designed to give you a broad understanding of the environmental, political and socio-economic context for current developments in renewable energy. The course examines the extent of current energy resources and how energy markets function. It covers some energy basics you will need for the rest of the programme (e.g. thermodynamics, efficiency conversions) as well as environmental issues associated with energy use, climate change and the political and policy challenges involved in managing energy supply and achieving energy security.

- Economics of renewable energy
This course gives an understanding of the economic principles and mechanisms which affect energy markets today. It covers price mechanisms, the economics of extracting energy and the cost-efficiency of renewable energy technologies. You will learn about economic instruments used by policy-makers to address environment and energy issues, economic incentives to stimulate renewable energy development and about environmental valuation.

- Environmental Policy & Risk
This course explores the legal and policy context in which renewable energy is being exploited. You will gain an understanding of international law, particularly the Law of the Sea, property rights and how these relate to different energy resources. The course also looks at regulatory issues at the international, European and UK level, which affect how energy developments are taken forward, as well as risk assessment and management in the context of renewable energy developments.

- Environmental Processes
Particularly for those without a natural science background, this course provides a broad overview of the environmental processes which are fundamental to an understanding of renewable energy resources and their exploitation. You will study energy flows in the environment, environmental disturbance associated with energy use, and an introduction to the science of climate change. You will also learn about ecosystems and ecological processes including population dynamics and how ecosystems affect and interact with energy generation.

- Renewable Technology I: Generation
This course explores how energy is extracted from natural resources: solar, biomass, hydro, wind, wave and tide. It examines how to assess and measure the resources, and the engineering solutions which have been developed to extract energy from them. You will develop an understanding of the technical challenges and current issues affecting the future development of the renewable energy sector.

- Renewable Technology II: Integration
This course explores the technical aspects of generating renewable energy and integrating it into distribution networks. You will learn about the electricity grid and how electrical power and distribution systems work. You will find out about different renewable fuel sources and end uses, and the challenges of energy storage.

- Development Appraisal
Looking at what happens when renewable energy technologies are deployed, this course examines development constraints and opportunities: policy and regulatory issues (including strategic environmental assessment, environmental impact assessment, landscape assessment, capacity issues and the planning system). It also looks at the financial aspects (valuation of capital assets, financing projects and the costs of generating electricity) and at project management.

- Development Project
This is a team project, where students have the opportunity to apply what they have learned through the other courses in relation to a hypothetical project. You have to look at a range of issues including resource assessment, site selection, development layout, consents, planning and economic appraisal, applying the knowledge and tools you have studied.

- Optional design project
For students who can demonstrate existing knowledge covered by one of the courses, there is the option of understanding a design project supervised by one of our engineers.

- Dissertation
This research project (equivalent in assessment to 4 taught courses) allows you to focus on a specific area of interest, with opportunities to collaborate with businesses and other stakeholders. You choose your dissertation subject, in discussion with your supervisor.

- Additional information
If you study at our Orkney Campus, you will also benefit from a number of activities including guest lectures and practical sessions, which help to develop your skills and knowledge in your field of study, and offer opportunities to meet developers and others involved in the renewable energy industry.

Scholarships available

We have a number of fully funded Scottish Funding Council (SFC) scholarships available for students resident in Scotland applying for Renewable Energy Development (RED) MSc. Find out more about this scholarship and how to apply http://www.hw.ac.uk/student-life/scholarships/postgraduate-funded-places.htm .

English language requirements

If your first language is not English, or your first degree was not taught in English, we’ll need to see evidence of your English language ability. The minimum requirement for English language is IELTS 6.5 or equivalent. We offer a range of English language courses (See http://www.hw.ac.uk/study/english.htm ) to help you meet the English language requirement prior to starting your masters programme:
- 14 weeks English (for IELTS of 5.5 with no more than one skill at 4.5);
- 10 weeks English (for IELTS of 5.5 with minimum of 5.0 in all skills);
- 6 weeks English (for IELTS 5.5 with minimum of 5.5 in reading & writing and minimum of 5.0 in speaking & listening)

Distance learning students

Please note that independent distance learning students who access their studies online will be expected to have access to a PC/laptop and internet.

Find information on Fees and Scholarships here http://www.postgraduate.hw.ac.uk/prog/msc-renewable-energy-development-red-/

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Energy Engineering is the branch of engineering concerned with the design and the management of energy plants and their components in order to ensure the best use of the available resources with the minimum environmental impact. Read more

Mission and goals

Energy Engineering is the branch of engineering concerned with the design and the management of energy plants and their components in order to ensure the best use of the available resources with the minimum environmental impact. Energy plants are systems in which energy forms are transformed and utilized. To name a few examples: large thermal power stations, air-conditioning and climate control equipment for residences and offices, vehicle engines, airplane propellers, solar panels etc.
The Master of Science in Energy Engineering prepares professionals to design, select and use the main technologies in energy transformation, to actively follow scientific improvements and to operate effectively in a competitive and multi-disciplinary industrial context, characterized by significant environmental, regulatory and safety constraints. Students will analyze broad themes as well as specific subjects for which both a rigorous methodological approach to thermodynamics and an open attitude towards related interdisciplinary topics are required.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/energy-engineering/energy-engineering-track/

Professional opportunities

Graduates can find employment in several sectors: in the technical area of designing, testing, running, and maintaining the energy systems, like heating and cooling systems, thermal power and hydro-electric power plants, engines, oil and gas fields; in the energy management area; and in utilities and public boards that supply energy as electricity and natural gas.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Energy_Engineering_MI.pdf
Energy Engineering is the branch of engineering concerned with the design and the management of energy plants and their components in order to ensure the best use of the available resources with the minimum environmental impact. Energy plants are
systems in which energy forms are transformed and utilized. To name a few examples: large thermal power stations, air-conditioning and climate control equipment for residences and offices, vehicle engines, airplane propellers, solar panels etc. The Master of Science in Energy Engineering prepares professionals to design, select and use the main technologies in energy transformation, to actively follow scientific improvements and to operate effectively in a competitive and multi-disciplinary industrial context, characterized by significant environmental, regulatory and safety constraints. Students will analyze broad themes as well as specific subjects for which both a rigorous methodological approach to thermodynamics and an open attitude towards related interdisciplinary topics are required.
Graduates can find employment in several sectors: in the technical area of designing, testing, running, and maintaining the energy systems, like heating and cooling systems, thermal power and hydro-electric power plants, engines, oil and gas fields; in the energy management area; and in utilities and public boards that supply energy as electricity and natural gas. The programme is taught in English.

Subjects

- Five tracks available: Power Production; Heating, Ventilation and Air-Conditioning; Oil and Gas Engineering; Energy Engineering for an Environmentally Sustainable World (offered on Piacenza campus, see separate leaflet); Energy for Development.

- Subjects and courses common to all the tracks: Heat and Mass Transfer; Fundamentals of Chemical Processes; Advanced Energy Engineering and Thermoeconomics;; Combustion and Safety; Energy Conversion or Refrigeration, Heat Pumps and Thermal Power Systems and Components; Energy Economics or Project Management or Management Control Systems; Graduation Thesis.

- Optional subjects according to the selected track: Development Economy; Engineering and Cooperation for Development; Power Production from Renewable Sources; Engineering of Solar Thermal Processes; Petroleum Reservoir Engineering; Petroleum Technology and Biofuel; Transport Phenomena in the Reservoirs; CFD for Energy Engineering Analysis; System and Electrical Machines; Advanced Energy Systems; Dynamic Behavior and Diagnostics of Machines; Materials for Energy; Turbomachinery; Internal Combustion Engines; Air Conditioning and Room Pollutant-Controlling Plants, Energy Savings and Renewable Energies in Buildings; Applied Acoustics and Lighting; Design of Thermal Systems; Energy Systems and Low-Carbon Technologies; Air Pollutions and Control Engineering; Operation and Control of Machines for Power Generation; Bio-energy and Waste-to-Energy Technologies; Smart Grids and Regulation for Renewable Energy Sources.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/energy-engineering/energy-engineering-track/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/energy-engineering/energy-engineering-track/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

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This programme is appropriate for you if are seeking to develop the skills and confidence to address the critical global challenges of energy and diminishing natural resources. Read more
This programme is appropriate for you if are seeking to develop the skills and confidence to address the critical global challenges of energy and diminishing natural resources. Clean energy, optimal use of resources and the economics of climate change are the key issues facing society, and form the fundamental themes of this programme.

Course details

You explore the world’s dependency on hydrocarbon-based resources, together with strategies and technologies to decarbonise national economies. The course examines global best practice, government policies, industrial symbiosis and emerging risk management techniques. You also address the environmental, economic and sociological (risk and acceptability) impacts of renewable energy provision and waste exploitation as central elements.

The programme develops the problem-solvers and innovators needed to face the enormous challenges of the 21st century - those who can play key roles in driving energy and environmental policies, and in formulating forward-looking strategies on energy use and environmental sustainability at corporate, national and global scales.

What you study

For the PgDip award you must successfully complete 120 credits of taught modules. For an MSc award you must successfully complete the 120 credits of taught modules and a 60-credit master's research project.

Energy, environment, risk managing projects, sustainability and integrated waste management are the main foci of the programme, but you also explore the financial aspects of energy and environmental management. Economics is integral to the development of policies and is often a key influencing factor.

This programme aims to develop a comprehensive knowledge and understanding of the role and place of energy in the 21st century and the way the environment impinges on the types of energy used and production methods. It also aims to investigate the environment as it is perceived, and contextualise its actual importance to mankind. Specific objectives for this course are to establish the financial validity for the pursuit of alternative energy forms and management of the environment.

You are encouraged to take up opportunities of voluntary placements with local industries to conduct real-world research projects. These placements are assessed in line with the assessment criteria and learning outcomes of the Project module.

Examples of past MSc research projects:
-The taxonomy of facilitated industrial symbioses
-Assessment of the climate change impacts of the Tees Valley
-Exploring the links between carbon disclosure and carbon performance
-Hydrothermal carbonisation of waste biomass
-Quantifying the impact of biochar on soil microbial ecology
-Potential for biochar utilisation in developing rural economies
-Carbon trading opportunities for renewable energy projects in developing countries
-Exploring the potential for wind energy in Libya
-Demand and supply potential of solar panel installations
-A feasibility study of the application of zero-carbon retrofit technologies in building communal areas
-Energy recovery from abandoned oil wells through geothermal processes

Core modules
-Concepts of Sustainability
-Economics of Climate Change
-Energy and Global Climate Change
-Global Energy Policy
-Integrated Waste Management and Exploitation
-Project
-Research Methods and Proposal

Modules offered may vary.

Teaching

The course provides a number of contact teaching and assessment hours (through lectures, tutorials, projects, assignments), but you are also expected to spend time on your own, called 'self-study' time, to review lecture notes, prepare course work assignments, work on projects and revise for assessments. For example, each 20-credit module typically has around 200 hours of learning time.

In most cases, around 60 hours are spent in lectures, tutorials and in practical exercises. The remaining learning time is for you to gain a deeper understanding of the subject. Each year of full-time study consists of modules totalling 180 credits; hence, during one year of full-time study a student can expect to have 1,800 hours of learning and assessment.

Modules are assessed by a variety of methods including examination and in-course assessment with some utilising other approaches such as group-work or verbal/poster presentations.

Employability

There may be short-term placement opportunities for some students, particularly during the project phase of the course. This University is also in the process of seeking accreditation for the Waste Management module from the Chartered Institution of Wastes Management.

Successful graduates from this course are well placed to find employment. As an energy and environmental manager, you might find yourself in a role responsible for overseeing the energy and environmental performance of private, public and voluntary sector organisations, as well as in a wide range of engineering industries.

Energy and environmental managers examine corporate activities to establish where improvements can be made and ensure compliance with environmental legislation across the organisation. You might be responsible for reviewing the whole operation, carrying out energy and environmental audits and assessments, identifying and resolving energy and environmental problems and acting as agents of change. Your role could include the training of the workforce to develop the ability to recognise their own contributions to improved energy and environmental performance.

Your role may also include the development, implementation and monitoring of energy and environmental strategies, policies and programmes that promote sustainable development at corporate, national or global levels.

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This is a 12 month full-time MSc degree course (See http://www.postgraduate.hw.ac.uk/prog/msc-marine-renewable-energy/#overview ) taught at our Orkney Campus. Read more

Overview

This is a 12 month full-time MSc degree course (See http://www.postgraduate.hw.ac.uk/prog/msc-marine-renewable-energy/#overview ) taught at our Orkney Campus. It involves studying 8 taught courses. If you can demonstrate that you have already mastered the subject, you may apply for an exemption from one of the taught courses and undertake a Design Project instead. The MSc programme is completed with a research dissertation equivalent to 4 taught courses.

For more information visit http://www.hw.ac.uk/schools/life-sciences/research/icit.htm

Distance Learning

The Marine Renewable Energy MSc/Diploma is also available for independent distance learning. For distance learners, the main difference is that you will undertake the Development Project alone rather than as part of a group. You can still obtain the full MSc in Marine Renewable Energy, or you can opt to study fewer courses, depending on your needs.

Scholarships available

We have a number of fully funded Scottish Funding Council (SFC) scholarships available for students resident in Scotland applying for Marine Renewable Energy. Find out more about this scholarship and how to apply http://www.hw.ac.uk/student-life/scholarships/postgraduate-funded-places.htm .

Programme content

The Diploma and MSc degree course involves studying the 8 taught courses outlined below. If a student can demonstrate that they have already mastered the subject, they may undertake a Development Project instead of one of these courses.

- Energy in the 21st Century
This course is designed to give you a broad understanding of the environmental, political and socio-economic context for current developments in renewable energy. The course examines the extent of current energy resources and how energy markets function. It covers some energy basics you will need for the rest of the programme (e.g. thermodynamics, efficiency conversions) as well as environmental issues associated with energy use, climate change and the political and policy challenges involved in managing energy supply and achieving energy security.

- Economics of renewable energy
This course gives an understanding of the economic principles and mechanisms which affect energy markets today. It covers price mechanisms, the economics of extracting energy and the cost-efficiency of renewable energy technologies. You will learn about economic instruments used by policy-makers to address environment and energy issues, economic incentives to stimulate renewable energy development and about environmental valuation.

- Environmental Policy & Risk
This course explores the legal and policy context in which renewable energy is being exploited. You will gain an understanding of international law, particularly the Law of the Sea, property rights and how these relate to different energy resources. The course also looks at regulatory issues at the international, European and UK level, which affect how energy developments are taken forward, as well as risk assessment and management in the context of renewable energy developments.

- Oceanography & Marine Biology
This course is designed to give you an understanding of the science of waves and tides, and how this affects efforts to exploit energy from these resources. You will also learn about marine ecosystems and how these may be impacted by energy extraction and about the challenges and impacts associated with carrying out engineering operations in the marine environment.

- Marine Renewable Technologies
You will gain an understanding of renewable energy technologies which exploit wind, wave and tidal resources. The focus is on technical design issues which developers face operating in the marine environment, as well as the logistics of installation, operations and maintenance of marine energy converters.

- Renewable Technology: Integration
This course explores the technical aspects of generating renewable energy and integrating it into distribution networks. You will learn about the electricity grid and how electrical power and distribution systems work. You will find out about different renewable fuel sources and end uses, and the challenges of energy storage.

- Development Appraisal
Looking at what happens when renewable energy technologies are deployed, this course examines development constraints and opportunities: policy and regulatory issues (including strategic environmental assessment, environmental impact assessment, landscape assessment, capacity issues and the planning system). It also looks at the financial aspects (valuation of capital asses, financing projects and the costs of generating electricity) and at project management.

- Development Project
This is a team project, where students have the opportunity to apply what they have learned through the other courses in relation to a hypothetical project. You have to look at a range of issues including resource assessment, site selection, development layout, consents, planning and economic appraisal, applying the knowledge and tools you have studied.

- Dissertation
This research project (equivalent in assessment to 4 taught courses) allows you to focus on a specific area of interest, with opportunities to collaborate with businesses and other stakeholders. You choose your dissertation subject, in discussion with your supervisor.

- Additional information
If you study at our Orkney Campus, you will also benefit from a number of activities including guest lectures and practical sessions which help to develop your skills and knowledge in your field of study, and offer opportunities to meet developers and other involved in the renewable energy industry.

English language requirements

If your first language is not English, or your first degree was not taught in English, we’ll need to see evidence of your English language ability. The minimum requirement for English language is IELTS 6.5 or equivalent. We offer a range of English language courses (http://www.hw.ac.uk/study/english.htm ) to help you meet the English language requirement prior to starting your masters programme:
- 14 weeks English (for IELTS of 5.5 with no more than one skill at 4.5);
- 10 weeks English (for IELTS of 5.5 with minimum of 5.0 in all skills);
- 6 weeks English (for IELTS 5.5 with minimum of 5.5 in reading & writing and minimum of 5.0 in speaking & listening)

Distance learning students

Please note that independent distance learning students who access their studies online will be expected to have access to a PC/laptop and internet.

Find information on Fees and Scholarships here http://www.postgraduate.hw.ac.uk/prog/msc-marine-renewable-energy/#overview

Visit the Marine Renewable Energy MSc/Diploma page on the Heriot-Watt University web site for more details!

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Whether you are a graduate looking for a career in environmental management or an experienced environmental professional, our Environmental Management MSc enables you to develop the knowledge and skills required to implement environmentally sustainable solutions within businesses and organisations around the world. Read more
Whether you are a graduate looking for a career in environmental management or an experienced environmental professional, our Environmental Management MSc enables you to develop the knowledge and skills required to implement environmentally sustainable solutions within businesses and organisations around the world.

About the course

Environmental Management is of increasing importance to all types of organisations both within the UK and worldwide; there is a growing need for qualified and trained environmental managers and, as environmental challenges become ever more apparent, this demand shows no signs of abating.

Our MSc in Environmental Management provides a flexible and broad approach to study and provides a firm grounding in the essentials of environmental management, including environmental auditing, the choice, design and use of a range of environmental tools and methods including EIA, ERA, Lifecycle Assessment and knowledge of environmental policy and legislation. Studying on this accredited Environmental Management MSc is the first step to becoming a Chartered Environmentalist.

Three modules are accredited by the Institute of Environmental Management and Assessment (IEMA). Successful completion allows you to apply for IEMA Graduate or Practitioner membership, with exemption from selected IEMA membership examinations. All modules are accredited by the Chartered Institution of Water and Environmental Management (CIWEM) for Graduate membership.

Five core modules are taken and students then choose three optional modules. Students will begin their studies, both full-time and part time, with a core module in Sustainability and Environmental Systems.

To obtain a Master's degree you need to carry out a supervised research project comprising of another taught module, Research methods and a 10,000-15,000 word research project. The project can be based on an environmental management issue that interests you or is relevant to your organisation.

Why choose this course?

-Over 20 years’ experience of teaching Environmental Management and delivering highly employable graduates to the sector
-Flexible modes of study: full-time, part-time, September start, January start
-MSc programmes and key modules accredited by the Chartered Institution of Water and Environmental Management (CIWEM) and the Institute of Environmental Management and Assessment (IEMA)
-Teaching centred on 2-3 day ‘short courses’ to allow study while managing external commitments
-Selected key textbooks provided within fees, together with catering on short courses

Professional Accreditations

Three modules are accredited by the Institute of Environmental Management and Assessment (IEMA) for Associate membership (giving exemption from the Associate Entry Examination). All modules are accredited by the Chartered Institution of Water and Environmental Management (CIWEM) for graduate membership.

Careers

Environmental Management is of increasing importance to all types of organisations both within the UK and worldwide; there is a growing need for qualified and trained environmental managers and, as environmental challenges become ever more apparent, this demand shows no signs of abating. Graduates from our Environmental Management MSc programmes have embarked on careers with a wide variety of employers within the environmental management sector, including environmental consultancy, the water supply industry and Government agencies such as the Environment Agency and the Department for Environment Food & Rural Affairs. Graduates have also commenced doctoral level studies and developed careers in research and education.

Teaching methods

The programme approach integrates blended learning, combining face-to-face teaching and tutorials with online learning materials, easy contact with tutors and online submission of assignments.

All modules are delivered as intensive two or three day short courses that run Fridays and Saturday or Thursday to Saturday.
Full-time students attend tutorials in the weeks following a short course, receiving face-to-face support.

Part-time students attend courses at the University for approximately six working days a year and complete assignments through use of our outstanding virtual learning environment, Studynet. Most part time students complete this course within two years but you are given a maximum of five to complete.

Assessment can include reports, essays, seminars and online tests. Assignments are often directly related to environmental management in the workplace or field.

You have access to excellent University facilities including a field station, state-of-the-art Learning Resource Centre and a brand new Science Building.

Structure

Core Modules
-Environmental Management Tools and Methods
-Environmental Policy and Governance
-Foundation in Environmental Auditing
-Management Skills for Environmental Management

Optional
-Crop Pathogens, Pests and Weeds
-Crop Protection; Principles & Practice
-Ecology and Conservation
-Environmental Management Individual Research Project
-Environmental Management Systems Implementation
-Environmental Management Tools and Methods
-Foundation in Environmental Auditing
-Integrated Waste and Pollution Management
-Research Methods
-Sustainability and Environmental Systems
-Sustainable Energy
-Transport Policy & Travel Planning
-Water Pollution Control
-Water Resources

Read less
*Why do energy efficiency measures often fail?. *How will we transition into a post-carbon energy system?. *Why do some energy technologies spread, while others disappear?. Read more
*Why do energy efficiency measures often fail?
*How will we transition into a post-carbon energy system?
*Why do some energy technologies spread, while others disappear?
*How can people be persuaded to change their energy habits?

The MSc in Energy and Society investigates energy systems from all angles. On this course you will look at energy in practice, what it means to make an energy transition, what we mean by energy justice, and how energy practices change.

The programme brings in leading experts in energy studies at Durham from Anthropology, Engineering, Economics, Law, Geography, Geosciences and many other departments. It is taught through intensive block-teaching, field-study, original dissertation research and a range of optional modules that complement the core teaching. You will learn about current and new energy technologies, histories of energy, how to understand energy policy, and how to study energy practices.

A broad range of optional subjects enables you to tailor the course according to your particular interests – you can take modules in law, international politics, advanced engineering, geography, risk, development or resilience, depending on your prior qualifications. In your fully supported personal research project you will deepen your expertise in your chosen area.

The full-time course consists of two terms of teaching, during which students are introduced to the range of research questions and methods, and a dissertation, involving the design, development and implementation of an independent research project. Students work closely with academic staff, and have the opportunity to become involved in active research projects.

Compulsory modules

-Dissertation
-Energy in Practice (Field Study)
-Context and Challenges in Energy
-Energy Society and Energy Practices

Optional modules from across the University and have previously included:

-Academic and Professional Skills in Anthropology
-Fieldwork and Interpretation
-Group Renewable Energy Design Project
-Key Issues in Sociocultural Theory
-Society, Energy, Environment and Resilience
-Computational Methods for Social Sciences
-Anthropology and Development
-Negotiating the Human
-Statistical Analysis in Anthropology
-Energy, Markets and Risk
-Renewable Energy and the Environment
-Risk Frontiers

Please see http://www.durham.ac.uk/anthropology/postgraduatestudy/taughtprogrammes/mscenergyandsociety for further information on modules.

Dissertation

We place an emphasis on independent learning. This is supported by the University’s virtual learning environment, extensive library collections and informal contact with tutors and research staff. We consider the development of independent learning and research skills to be one of the key elements of our postgraduate taught curriculum and one which helps our students cultivate initiative, originality and critical thinking.

The dissertation is a significant piece of independent research that constitutes a synthesis of theory, method and practice in anthropology and is supported by an individual supervisor and the dissertation coordinator.

Previous dissertations and research projects as part of the course have been undertaken in partnership with DONG Energy UK, Haringey Borough of London, National Energy Action, Durham County Council, energy enterprises and community energy schemes.

Careers

This course attracts high quality applicants from all over the world and delivers highly-skilled graduates who are able to communicate across disciplines and countries to further environmental progress and energy justice. Graduates of the MSc will be in demand from industry, community organisations, Non-Governmental Organisations and governments around the world. Graduates have gone on to work in Energy justice organisations, local authorities, energy consultancies and further Doctoral study.

Student support

Throughout the programme, all students meet regularly with the degree tutor, who provides academic support and guidance. Furthermore, all members of teaching staff have weekly office hours when they are available to meet with students on a ‘drop-in’ basis. In term time, the department also has an extensive programme of departmental and research group seminars which postgraduate students are encouraged and expected to attend. The undergraduate Anthropology Society also organises its own visiting lecturer programme. We ensure that we advertise any other relevant seminars and lectures in Durham, Newcastle and further afield, and encourage students to attend relevant conferences.

Before the academic year starts, we provide information on preparation for the course. On arrival we have induction sessions and social events, headed by the Director of Postgraduate Studies and attended by both academic and administrative staff. Students also attend an “Introduction to Research Groups in Anthropology”.

Postgraduate study at Durham University

The MSc Energy and Society is based in Durham University’s Department of Anthropology in association with the Durham Energy Institute. Durham has one of the largest Anthropology departments in the world with 40 research active academic teaching staff working across the full range of the discipline. Our Anthropology department is ranked in the top 50 of the prestigious QS World University Subject Rankings. The overall QS rankings also placed Durham 54th in the world for citations, recognising the impact and influence of its research among other academics, and 31st globally for employer reputation, giving recognition to the quality of, and international demand for, Durham’s graduates.

Students on this course can become members of the Durham Energy Institute (DEI) community and can attend its wide range of seminars and events, benefitting from its extensive network of contacts in the energy sector. DEI ( http://www.durham.ac.uk/dei/ ) covers the spectrum of energy research from technological innovation, to the social, political and economic dimensions of energy. DEI addresses energy challenges collaboratively through strong partnerships with industry, international partners, governments, community groups and other academic institutions. This ensures our research is relevant, timely and effective.

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