• Swansea University Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Anglia Ruskin University Featured Masters Courses
  • University of Southampton Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Goldsmiths, University of London Featured Masters Courses
  • Jacobs University Bremen gGmbH Featured Masters Courses
  • Ross University School of Veterinary Medicine Featured Masters Courses
University of Manchester Featured Masters Courses
Vlerick Business School Featured Masters Courses
Queen Mary University of London Featured Masters Courses
University of Reading Featured Masters Courses
University of Cambridge Featured Masters Courses
"greenhouse"×
0 miles

Masters Degrees (Greenhouse)

We have 45 Masters Degrees (Greenhouse)

  • "greenhouse" ×
  • clear all
Showing 1 to 15 of 45
Order by 
Change the world. Join the unique Master of Engineering Studies (Renewable Energy Systems) to tackle one of the most important issues our world faces today. Read more

Change the world

Join the unique Master of Engineering Studies (Renewable Energy Systems) to tackle one of the most important issues our world faces today.

The Master of Engineering Studies (Renewable Energy Systems) is a unique postgraduate programme in New Zealand.

Taught in conjunction with world-renowned Murdoch University in Australia, it is the only fully-focussed renewable energy postgraduate programme in New Zealand. The programme has been running for over fifteen years.

This qualification is suitable if you either have an undergraduate engineering degree and wish to specialise in renewable energy, or you have found yourself working in a renewable-energy-related role and need to upskill. You do not have to have an engineering degree to enrol.

Setting the global agenda

Let our experts help you develop your own expertise. We bring a solid base of experience to your learning from our Centre for Energy Research, established at Massey in 1997 following over 25 years of teaching and research work undertaken in the areas of renewable energy, energy efficiency and energy management. 

We also bring the most relevant and recent research to your learning. You will learn the theory and practice behind energy management, renewable energy and climate change from lecturers who have been working internationally, contributing to research and policy through panels that are setting the global agenda.

Real-world learning

You will gain an in-depth understanding of the theory of renewable energy systems, but also focus on practical information that can be applied to real-world situations. This could be through using the international Long Range Energy Alternatives Planning System (LEAP) model to assess climate change mitigation options for a country, city or community.

You will also learn how to measure renewable energy resources, and understand the challenges of providing energy efficiency or renewable energy systems in developing countries as part of sustainable development.

Your study includes examining solar radiation, wind, hydro, tidal, wave and biomass systems and their design, including economics and performance. You will look at the challenges in assessing, designing, introducing and maintaining small-scale renewable energy technologies in developing countries and study the scientific theory of global warming, climate modeling and social and technological approaches to reducing greenhouse emissions including greenhouse gas accounting principles.

The programme also covers the social issues to change human behaviour regarding the deployment of renewable energy systems and related greenhouse gas emission reductions.

Flexibility

You can study towards the Master of Engineering Studies on campus, or study via our distance learning. This gives you the flexibility to remain in full-time employment while studying. Massey University has been offering distance education for over 50 years and you will be able to take advantage of our well-developed systems for teaching and learning.

Dig deeper

The renewable energy systems major includes an optional research project, where you can either investigate a topic you are interested in, or work with us to develop an industry-relevant piece of work.

A year full time

The Master of Engineering Studies is a 120 credit qualification able to be completed in one year full-time, or part-time between 2.5 and five years..

Why postgraduate study?

Postgraduate study is hard work but hugely rewarding and empowering. The Master of Engineering Studies will push you to produce your best creative, strategic and theoretical ideas. The workload replicates the high-pressure environment of senior workplace roles.

Not just more of the same

Postgraduate study is not just ‘more of the same’ undergraduate study. Our experts are there to guide but if you have come from undergraduate study, you will find that postgraduate study demands more in-depth and independent study. It takes you to a new level in knowledge and expertise especially in planning and undertaking research.



Read less
Join us at our. Masters Open Day. to find out more about our courses. Climate Change is a growing issue for environmental policy makers at the international, national and sub-national levels, as well as for environmental managers and experts in public, private and non-profit making organisations. Read more

Join us at our Masters Open Day to find out more about our courses.

Climate Change is a growing issue for environmental policy makers at the international, national and sub-national levels, as well as for environmental managers and experts in public, private and non-profit making organisations.

This course provides you with a unique combination of training on the physical, social and policy aspects of climate change and on broader environmental policy and governance.

You’ll receive a solid foundation in the physical and social science of climate change and its impacts, including adaptation to, and mitigation of, climate change.

You’ll develop a critical understanding of the policy tools available to promote environmental protection.

This Masters combines modules taught at the School of Earth and Environment, with optional modules from the School of Geography and the School of Politics and International Studies.

Our teaching draws on the latest cutting-edge research and is delivered by experts and world’s leading researchers on climate change policy (e.g. IPCC lead authors, and a DEFRA UK lead advisor) to give you in-depth knowledge and guidance.

No other UK university can offer the same level and breadth of expert teaching in climate change and environmental policy.

Course highlights:

Be taught by three lead authors of the Intergovernmental Panel on Climate Change (IPCC), which advises world governments on the evolving and complex issue of climate change, and a lead advisor to the UK's Department for Environment, Food & Rural Affairs (DEFRA). All academics have won teaching awards.

Engage with some of the world's leading researchers from the Priestley International Centre for Climate (PICC), the ESRC-funded Centre for Climate Change Economics and Policy (CCCEP) and the RCUK-funded UK Energy Research Centre (UKERC). They have published high profile papers with past students.

Attend excellent seminars and talks run by the School and its research centres, where you will access the latest, cutting-edge research delivered by leading climate policy makers and advisors. Plus, attend other seminars run by the School of Geography and School of Politics and International Studies. Ideal if you want to build, or extend your network to enhance your career.

In addition to a free field course to East Yorkshire, choose an optional overseas field course to Tanzania, which provides an opportunity for you to gain practical experience and apply classroom-based learning first-hand in a developing country context. Ideal if you are considering working in an international capacity in this field.

Course content

When completed on a full-time basis, this 12 month Masters is split into 3 semesters.

In your semester 1, you’ll develop a grounding in the physical and social sciences – important for understanding climate mitigation and adaptation.

You’ll also examine the multiple pathways through which human-environment interaction is governed.

You’ll become familiar with appropriate research methods and gain the research skills relevant to your dissertation project.

In semester 2, your studies will give you an overview of climate change impact assessment and predictions, along with key concerns and strategies of adaptation to climate change.

You’ll explore the relative significance of main sources of greenhouse gases and the potential, technologies and strategies for reducing them.

You’ll develop an understanding of the key challenges for controlling greenhouse gas emissions, alongside the critical political issues related to mitigation.

During semester 3, you’ll propose and undertake an extended research project leading to the submission of a 12,000-word dissertation in August.

This dissertation gives you the opportunity to examine the detail of an issue of your choice.

When completed on a part-time basis, the course runs for 24 months, with each year split into 3 semesters. You will take complusory and optional modules in each semester, followed by an extended research project leading to the submission of a 12,000-word dissertation in semester 3 of your final year.

Course structure

Compulsory modules

  • Research Methods 15 credits
  • Research Project 60 credits
  • Environmental Policy and Governance 15 credits
  • Climate Change: Physical Science Basis 15 credits
  • Climate Change: Impacts and Adaptation 15 credits
  • Climate Change Mitigation 15 credits

Optional modules

  • Environmental Assessment 15 credits
  • International Relations and the Environment 30 credits
  • Standards and Tools for Business, Environment and Corporate Social Responsibility 15 credits
  • Business, Environment and Sustainability 15 credits
  • Introduction to Ecological Economics 15 credits
  • Environmental Economics and Policy 15 credits
  • Delivering Sustainability Through Projects 15 credits
  • Introduction to Sustainability 15 credits
  • Critical Perspectives in Environment and Development 15 credits
  • Environment-Development Overseas Field Course 15 credits
  • Tools and Techniques in Ecological Economics 15 credits
  • Terrestrial Biosphere in the Earth System 15 credits

For more information on typical modules, read Climate Change and Environmental Policy MSc Full Time in the course catalogue

For more information on typical modules, read Climate Change and Environmental Policy MSc Part Time in the course catalogue

Learning and teaching

You will learn through a variety of teaching methods to help you develop both generic and subject-specific skills.

This includes lectures, practical workshops, field trips (UK and overseas), computer lab sessions, research seminars and project work (individual and groupwork).

Practical exercises focus around real-world scenarios and case studies to produce optimal solutions including familiarisation with state-of-the-art technical approaches, software and the regulatory regimes that companies and public sector organisations operate within.

The research-intensive environment of the School ensures that your course material is both up-to-date and research led.

You'll also learn the scientific and rational principles lying behind the practical approaches used in the world outside academia, so that your skills keep pace with changes in technology or the regulatory environment.

You also have access to the excellent research seminars and talks run by the School of Earth and Environment and its research centres, plus those organised by School of Geography and School of Politics and International Studies.

Facilities

The School of Earth and Environment’s £23m building gives you access to world-class research, teaching and facilities.

Assessment

You will be assessed through a variety of ways including both written and oral assignments, exams and poster presentations.



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

MSc Biosystems Engineering

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

Programme summary

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

Thesis tracks

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

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

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

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

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

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

Your future career

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

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

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

Read less
The Plant Sciences programme has been designed to help meet the worldwide demand for scientific expertise in the development of plant and crop production and farming systems. Read more

MSc Plant Sciences

The Plant Sciences programme has been designed to help meet the worldwide demand for scientific expertise in the development of plant and crop production and farming systems.

Programme summary

Plant Sciences deals with crop production ranging from plant breeding to the development of sustainable systems for the production of food, pharmaceuticals and renewable resources. It is linked with a professional sector that is highly important to the world economy. The programme focuses on the principles of plant breeding, agro-ecology and plant pathology and the integration of these disciplines to provide healthy plants for food and non-food applications. Technological aspects of crop production are combined with environmental, quality, socio-economic and logistic aspects. Students learn to apply their knowledge to develop integrated approaches for sustainable plant production.

Specialisations

Crop Science
Sound knowledge of crop science is essential to develop appropriate cultivation methods for a reliable supply of safe, healthy food; while considering nature conservation and biodiversity. An integrated approach is crucial to studying plant production at various levels (plant, crop, farm, region). This requires a sound understanding of basic physical, chemical, and physiological aspects of crop growth. Modelling and simulation are used to analyse yield constraints and to improve production efficiency.

Greenhouse Horticulture
Greenhouse horticulture is a unique agro-system and a key economic sector in the Netherlands. It is the only system that allows significant control of (a-) biotic factors through protected cultivation. The advances in this field are based on technological innovations. This specialisation combines product quality with quality of production and focuses on production, quality- and chain management of vegetables, cut flowers and potted plants.

Natural Resource Management
The development of sustainable agro-ecosystems requires understanding of the complex relationships between soil health, cultivation practices and nutrient kinetics. Other important aspects include the interactions between agriculture and nature, and competing claims on productive land worldwide. Natural Resource Management provides knowledge and tools to understand the interactions between the biotic and abiotic factors in agro-systems to facilitate diverse agricultural demands: bulk vs. pharmaceutical products, food vs. biofuel, conservation of biodiversity, climate change, and eco-tourism.

Plant Breeding and Genetic Resources
Plant Breeding and Genetic Resources ranges from the molecular to the population level and requires knowledge of the physiology and genetics of cultivated plants. Plant breeding is crucial in the development of varieties that meet current demands regarding yield, disease resistance, quality and sustainable production. The use of molecular techniques adds to the rapid identification of genes for natural resistance and is essential for accelerating selection by marker assisted breeding.

Complete Online Master
In September 2015, Wageningen University started the specialisation "Plant Breeding" as the first complete online Master of Science. For more information go to http://www.wageningenuniversity.eu/onlinemaster.


Plant Pathology and Entomology
The investments made in crop production need to be protected from losses caused by biotic stress. Integrated pest management provides protection by integrating genetic resistance, cultivation practices and biological control. This specialisation focuses on the ecology of insects, nematodes and weeds, and the epidemiology of fungi and viruses, including transmission mechanisms. Knowledge of plantinsect, plant-pathogen, and crop-weed relations establishes the basis for studies in integrated pest management and resistance breeding.

Your future career

Graduates in Plant Sciences have excellent career prospects and most of them receive job offers before graduation. They are university-trained professionals who are able to contribute to the sustainable development of plant production at various integration levels based on their knowledge of fundamental and applied plant sciences and their interdisciplinary approach. Graduates with a research focus are employed at universities, research institutes and plant breeding or agribusiness companies. Other job opportunities are in management, policy, consultancy and communication in agribusiness and (non-) governmental organisations.

Alumnus Maarten Rouwet.
“I was born in Germany and raised in the East of the Netherlands. After high school I applied for the Bèta-gamma bachelor at the University of Amsterdam where I majored in biology. After visiting the master open day at Wageningen University I knew that the master Plant Sciences had something unique to offer. In my master, I specialised in plant breeding, an ever so interesting field of research. I just started my first job as junior biotech breeder of leavy vegetables at Enza Zaden, a breeding company in Enkhuizen. One of my responsibilities is to identify resistances in wild species of lettuce and to implement these in breeding programmes of cultivated lettuce.”

Related programmes:
MSc Biosystems Engineering
MSc Biotechnology
MSc Biology
MSc Forest and Nature Conservation
MSc Organic Agriculture
MSc Plant Biotechnology.

Read less
The Master of Science course in Energy Engineering is aimed at students trained as general engineers with skills on the new technologies relevant to the energy conversion and its rational use. Read more
The Master of Science course in Energy Engineering is aimed at students trained as general engineers with skills on the new technologies relevant to the energy conversion and its rational use. Candidates will be required to plan, design and manage energy systems blending creative solutions with up-to-date technologies relative to energy conversion and efficiency enhancement.

At the end of the course, engineers will be good at operating in the current technological/industrial environment - i.e. a dynamic and competitive one - and sensitive to the main industry, environment and security issues and standards.

The main aim of the course is to offer an in-depth theoretical and practical understanding of the most advanced energy conversion technologies, including renewable energy generation and energy storage.

Please visit http://www.en2.unige.it for any further information.

The Course is held at Savona Campus, in the city of Savona.

WHAT WILL YOU STUDY AND FUTURE PROSPECTS

The course consists of modules that include thermo-fluid dynamics and thermo-chemical dynamics, as well as fluid machinery and energy conversion systems (co-generation, fuel cells, power plants from renewable energy sources and smart grids), traditional energy and civil engineering plants, electric networks, economics, available and emerging technologies for reducing greenhouse gas emissions and environmental monitoring.

A rising interest in and increased urge for 20/20/20 policies in Europe has resulted in a growing industrial demand for highly qualified Energy Engineers with a sound knowledge and specific skills to analyze, design and develop effective solutions in a broad range of contexts. Furthermore, in the last few years both emerging industrial countries and developing ones have increased their awareness of environmental issues and energy production and started implementing large energy engineering projects thus boosting the job opportunities worldwide. The course is aimed at students seeking high qualification in the following main fields:

Energy conversion processes from chemical, bio-chemical, thermal sources into mechanical and electrical ones

Sustainable & Distributed Energy: renewable energy (solar, geothermal, wind, hydro), fuel cells, bio-fuels, smart power grids, low emission power plants Sustainable Development: C02 sequestration, LCA analysis, biomass exploitation, Energy Audit in buildings, energy from waste, recycling, modeling and experimental techniques devoted to optimum energy management.

The MSc course work in partnership with industries and research institutes in Liguria, in Italy and abroad.

WHAT DOES THE MASTER IN ENERGY ENGINEERING OFFER TO ITS STUDENTS

In the last years both industrialization and population growth have brought to a higher demand for sustainable energy, smart energy management with reduced environmental impact. As a result the MSc Energy Engineering was born out of the need to better cope with Sustainable Development issues and progress in energy conversion technologies, in including renewable energy generation and energy storage, NZE buildings, with an increasing attention devoted to greenhouse gas emissions reduction through a multidisciplinary approach.

This MSc course is taught in English and students are supported in achieving higher English language skills. The University of Genoa set its modern campus in Savona and in the last few years, public and private funds have been invested to improve its infrastructures, sport facilities, hall of residence, library and an auditorium.

The University of Genoa and Siemens jointly developed a smart polygeneration microgrid in Savona Campus – officially commissioned on February 2014.

Since then the campus has largely generated enough power to satisfy its own needs with the help of several networked energy producers, i.e. total capacity 250Kw of electricity and 300kW of heating.

The grid includes microgasturbines, absorption chillers, a photovoltaic plant, a solar power station and electrochemical and thermal storage systems.

This huge facility together with a series of laboratories located at the Campus (e.g. Combustion Lab, Energy Hub Lab) offer the students a unique opportunity for hands-on activities, e.g. to measure and investigate the performance of real scale innovative energy systems.

Read less
Society urgently needs experts with a multidisciplinary education in atmospheric and Earth System sciences. Climate change and issues of air quality and extreme weather are matters of global concern, but which are inadequately understood from the scientific point of view. Read more
Society urgently needs experts with a multidisciplinary education in atmospheric and Earth System sciences. Climate change and issues of air quality and extreme weather are matters of global concern, but which are inadequately understood from the scientific point of view. Not only must further research be done, but industry and business also need environmental specialists with a strong background in natural sciences. As new regulations and European Union directives are adopted in practice, people with knowledge of recent scientific research are required.

Upon graduating from the Programme you will have competence in:
-Applying experimental, computational and statistical methods to obtain and analyse atmospheric and environmental data.
-Knowledge applicable to solving global challenges such as climate change, air pollution, deforestation and issues related to water resources and eutrophication.
-Making systematic and innovative use of investigation or experimentation to discover new knowledge.
-Reporting results in a clear and logical manner.

The University of Helsinki will introduce annual tuition fees to foreign-language Master’s programmes starting on August 1, 2017 or later. The fee ranges from 13 000-18 000 euros. Citizens of non-EU/EEA countries, who do not have a permanent residence status in the area, are liable to these fees. You can check this FAQ at the Studyinfo website whether or not you are required to pay tuition fees: https://studyinfo.fi/wp2/en/higher-education/higher-education-institutions-will-introduce-tuition-fees-in-autumn-2017/am-i-required-to-pay-tuition-fees/

Programme Contents

The six study lines are as follows:
Aerosol Physics
Aerosol particles are tiny liquid or solid particles floating in the air. Aerosol physics is essential for our understanding of air quality, climate change and production of nanomaterials. Aerosol scientists investigate a large variety of phenomena associated with atmospheric aerosol particles and related gas-to-particle conversion using constantly improving experimental, theoretical, model-based and data analysis methods. As a graduate of this line you will be an expert in the most recent theoretical concepts, measurement techniques and computational methods applied in aerosol research.

Geophysics of the Hydrosphere
Hydrospheric geophysics studies water in all of its forms using physical methods. It includes hydrology, cryology, and physical oceanography. Hydrology includes the study of surface waters such as lakes and rivers, global and local hydrological cycles as well as water resources and geohydrology, the study of groundwater. Cryology focuses on snow and ice phenomena including glacier mass balance and dynamics, sea ice physics, snow cover effects and ground frost. Physical oceanography covers saline water bodies, focusing on describing their dynamics, both large scale circulation and water masses, and local phenomena such as surface waves, upwelling, tides, and ocean acoustics. Scientists study the hydrosphere through field measurements, large and small scale modelling, and formulating mathematical descriptions of the processes.

Meteorology
Meteorology is the physics of the atmosphere. Its best-known application is weather forecasting, but meteorological knowledge is also essential for understanding, predicting and mitigating climate change. Meteorologists study atmospheric phenomena across a wide range of space and time scales using theory, model simulations and observations. The field of meteorology is a forerunner in computing: the development of chaos theory, for example, was triggered by the unexpected behaviour of a meteorological computer model. Meteorology in ATM-MP is further divided into dynamic meteorology and biometeorology. Dynamic meteorology is about large-scale atmospheric dynamics, modelling and observation techniques, whereas biometeorology focuses on interactions between the atmosphere and the underlying surface by combining observations and modelling to study the flows of greenhouse gases and energy with links to biogeochemical cycles, for example. As a graduate of the meteorology line, you will be an expert in atmospheric phenomena who can produce valuable new information and share your knowledge.

Biogeochemical Cycles
Biogeochemistry studies the processes involved in cycling of elements in terrestrial and aquatic ecosystems by integrating physics, meteorology, geophysics, chemistry, geology and biology. Besides natural ecosystems, it also studies systems altered by human activity such as forests under different management regimes, drained peatlands, lakes loaded by excess nutrients and urban environments. The most important elements and substances studied are carbon, nitrogen, sulphur, water and phosphorus, which are vital for ecosystem functioning and processes such as photosynthesis. Biogeochemistry often focuses on the interphases of scientific disciplines and by doing so, it also combines different research methods. It treats ecosystems as open entities which are closely connected to the atmosphere and lithosphere. You will thus get versatile training in environmental issues and research techniques. As a graduate of this line you will be an expert in the functioning of ecosystems and the interactions between ecosystems and the atmosphere/hydrosphere/lithosphere in the context of global change. You will have knowledge applicable for solving global challenges such as climate change, air pollution, deforestation and issues related to water resources and eutrophication.

Remote Sensing
Remote sensing allows the collection of information about the atmosphere, oceans and land surfaces. Various techniques are applied for monitoring the state and dynamics of the Earth system from the ground, aircraft or satellites. While Lidar and radar scan from the surface or mounted on aircraft, instruments on polar orbiting or geostationary satellites permit measurements worldwide. In atmospheric sciences remote sensing has found numerous applications such as observations of greenhouse and other trace gases, aerosols, water vapour, clouds and precipitation, as well as surface observations, for example of vegetation, fire activity, snow cover, sea ice and oceanic parameters such as phytoplankton. Synergistic satellite data analysis enables the study of important processes and feedback in the climate system. Remote sensing advances climate research, weather forecasting, air quality studies, aviation safety and the renewable energy industry. As a graduate of the remote sensing line you will have broad expertise in the operational principles of remote sensing instruments as well as methods of data collection, analysis and interpretation.

Atmospheric Chemistry and Analysis
Atmospheric chemistry studies the composition and reactions of the molecules that make up the atmosphere, including atmospheric trace constituents and their role in chemical, geological and biological processes, including human influence. The low concentrations and high reactivity of these trace molecules place stringent requirements on the measurement and modelling methods used to study them. Analytical chemistry is the science of obtaining, processing, and communicating information about the composition and structure of matter and plays an essential role in the development of science. Environmental analysis consists of the most recent procedures for sampling, sample preparation and sample analysis and learning how to choose the best analytical methods for different environmental samples. Physical atmospheric chemistry studies focus on the reaction types and reaction mechanisms occurring in the atmosphere, with emphasis on reaction kinetics, thermodynamics and modelling methods. As a graduate of this line you will have understanding of the chemical processes of the atmosphere and the latest environmental analytical methods, so you will have vital skills for environmental research.

Programme Structure

The basic degree in the Programme is the Master of Science (MSc). The scope of the degree is 120 credits (ECTS). As a prerequisite you will need to have a relevant Bachelor’s degree. The possible major subjects are Physics, Meteorology, Geophysics, Chemistry, and Forest Ecology. The programme is designed to be completed in two years. Studies in ATM-MP consist of various courses and project work: lecture courses, seminars, laboratory work and intensive courses.

Your first year of studies will consist mainly of lecture courses. During the second year, you must also participate in the seminar course and give a presentation yourself. There is also a project course, which may contain laboratory work, data analysis, or theoretical or model studies. You will have to prepare a short, written report of the project. There are also several summer and winter schools as well as field courses for students in the Programme. Many of the courses take place at the Hyytiälä Forestry Field Station in Southern Finland. The intensive courses typically last 5–12 days and include a concise daily programme with lectures, exercises and group work.

Career Prospects

There is a global need for experts with multidisciplinary education in atmospheric and environmental issues. Governmental environmental agencies need people who are able to interpret new scientific results as a basis for future legislation. Industry, transportation and businesses need to be able to adapt to new regulations.

As a Master of Science graduating from the Programme you will have a strong background of working with environmental issues. You will have the ability to find innovative solutions to complex problems in the field of environmental sciences, climate change and weather forecasting. Graduates of the Programme have found employment in Meteorological Institutes and Environmental Administration in Finland and other countries, companies manufacturing instrumentation for atmospheric and environmental measurements and analysis, and consultancy companies. The Master's degree in ATM-MP also gives you a good background if you intend to proceed to doctoral level studies.

Internationalization

The Programme offers an international study environment with more than 30% of the students and teaching staff coming from abroad.

The ATM-MP is part of a Nordic Nordplus network in Atmosphere-Biosphere Studies, which gives you good opportunities to take courses currently in fourteen Nordic and Baltic universities. There are also several Erasmus agreements with European universities. The PanEurasian Experiment (PEEX) project provides you with opportunities to carry out part of your studies especially in China and Russia.

Research Focus

All the units teaching in the Programme belong to the National Centre of Excellence (FCoE) in Atmospheric Science – From Molecular and Biological processes to the Global Climate (ATM), which is a multidisciplinary team of the Departments of Physics, Forest Sciences and Chemistry at the University of Helsinki, the Department of Applied Physics at the University of Eastern Finland (Kuopio) and the Finnish Meteorological Institute.

The main objective of FCoE ATM is to quantify the feedbacks between the atmosphere and biosphere in a changing climate. The main focus of the research is on investigating the following topics:
1. Understanding the climatic feedbacks and forcing mechanisms related to aerosols, clouds, precipitation and biogeochemical cycles.
2. Developing, refining and utilising the newest measurement and modelling techniques, from quantum chemistry to observations and models of global earth systems.
3. Creating a comprehensive understanding of the role of atmospheric clusters and aerosol particles in regional and global biogeochemical cycles of water, carbon, sulphur, nitrogen and their linkages to atmospheric chemistry.
4. Integrating the results in the context of understanding regional and global Earth systems.

In addition to the research focus of FCoE, current research in hydrospheric geophysics at Helsinki University has an emphasis on cryology, with a focus on the effect of aerosols on Indian glaciers, the impact of climate change on the Arctic environment, the dynamics of the Austfonna ice cap in Svalbard, and the winter season in the coastal zone of the Baltic Sea.

Read less
A unique programme. Gain an in-depth understanding of global energy management issues and the tools to design more effective energy programmes with the Master of Engineering Studies (Energy Management). Read more

A unique programme

Gain an in-depth understanding of global energy management issues and the tools to design more effective energy programmes with the Master of Engineering Studies (Energy Management).

Find out more about the Master of Engineering Studies parent structure.

In the energy management major of the Master of Engineering Studies, you will gain an detailed understanding of energy efficiency, looking at detail of energy use in industry and commercial settings, as well as tools for energy systems analysis and efficient building design.

A unique qualification

It is a unique postgraduate programme in New Zealand. Taught in conjunction with world-renowned Murdoch University in Australia, it is the only fully-focussed energy management postgraduate programme in New Zealand. The programme has been running for over fifteen years.

Learning in a global context

Your learning will be set in the context of global renewable energy systems and tools. You will learn the detail of contemporary renewable energy issues including greenhouse science, global energy systems, policy, economics and management. This will specifically cover renewable energy devices, resources and system design.

Setting the global agenda

Let our experts help you develop your own expertise. We bring a solid base of experience to your learning from our Centre for Energy Research, established at Massey in 1997 following over 25 years of teaching and research work undertaken in the areas of renewable energy, energy efficiency and energy management. We also bring the most relevant and recent research to your learning. You will learn the theory and practice behind energy management, renewable energy and climate change from lecturers who have been working internationally, contributing to research and policy through panels that are setting the global agenda.

Flexibility

You can study towards the Master of Engineering Studies on campus, or study via our distance learning. This gives you the flexibility to remain in full-time employment while studying. Massey University has been offering distance education for over 50 years and you will be able to take advantage of our well-developed systems for teaching and learning. Part of your study will be a real-life energy management case study.

Dig deeper

The renewable energy systems major includes an optional research project, where you can either investigate a topic you are interested in, or work with us to develop an industry-relevant piece of work.

Real-world learning

You will gain an in-depth understanding of the theory of renewable energy systems, but also focus on practical information that can be applied to real-world situations. This could be through using the international Long Range Energy Alternatives Planning System (LEAP) model to assess climate change mitigation options for a country, city or community. You will also learn how to measure renewable energy resources, and understanding the challenges of providing energy efficiency or renewable energy systems in developing countries as part of sustainable development.

The programme also covers the social issues to change human behaviour regarding the deployment of renewable energy systems and related greenhouse gas emission reductions.

Specialise

This qualification is suitable if you either have an undergraduate engineering degree and wish to specialise in energy management, or you have found yourself working in a energy management-related role and need to upskill. You do not have to have an engineering degree to enrol.

A year full time

The Master of Engineering Studies is a 120 credit qualification able to be completed in one year full-time, or part-time between 2.5 and five years..

Why postgraduate study?

Postgraduate study is hard work but hugely rewarding and empowering. The Master of Engineering Studies will push you to produce your best creative, strategic and theoretical ideas. The workload replicates the high-pressure environment of senior workplace roles.

Not just more of the same

Postgraduate study is not just ‘more of the same’ undergraduate study. Our experts are there to guide but if you have come directly from undergraduate study, you will find that postgraduate study demands more in-depth and independent study. It takes you to a new level in knowledge and expertise especially in planning and undertaking research.



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

Programme description

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

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

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

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

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

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

Programme structure

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

Compulsory courses typically will be:

  • Atmospheric Quality and Global Change
  • Analysing the Environment
  • Land Use/Environmental Interactions
  • Analysing the Environment Study Tour
  • Dissertation

Option courses:

You will also choose four optional courses^. We particularly recommend the following:

  • Soil Protection and Management
  • Integrated Resource Management
  • Ecosystem Dynamics and Functions
  • Marine Systems and Policies
  • Archives: History, Geography, Politics
  • Carbon Capture and Transport
  • Culture, Ethics & Environment
  • Encountering Cities
  • Environmental Geochemistry
  • Foundations in Ecological Economics
  • Human Dimensions of Environmental Change and Sustainability
  • Principles of Environmental Sustainability
  • Principles of GIS
  • Project Appraisal
  • Understanding Environment and Development
  • Values and the Environment
  • Environmental Impact Assessment
  • Waste Reduction and Recycling
  • Sustainability of Food Production
  • Participation in Policy and Planning
  • Forests and Environment
  • Carbonate Sequence Stratigraphy
  • Climate Change and Corporate Strategy
  • Hyperspectral Remote Sensing
  • Integrated Resource Planning
  • Introduction to Environmental Modelling
  • Political Ecology
  • Ecosystem Values and Management
  • Soil Science Concepts and Application
  • Water Resource Management

Courses are offered subject to timetabling and availability and are subject to change.

Field trip

Part of this programme is a week-long study tour in spring. Past study tours have been held in France, Greece, Portugal, Israel and Morocco.

Learning outcomes

Students will:

  • develop a scientific understanding of some of the major processes which influence the quality of land, air and water resources
  • acquire knowledge of the most effective methods of environmental protection
  • develop expertise in the design and implementation of programmes of environmental protection
  • have the opportunity to study the integrated protection and management of particular ecosystems or resources

Career opportunities

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

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

Student experience

Would you like to know what it’s really like to study at the School of GeoSciences?

Visit our student experience blog where you can find articles, advice, videos and ask current students your questions.



Read less
Your programme of study. If you are interested in earth science, and environmental science but you want to specialise in the study of soil specifically the Aberdeen programme gives you in depth knowledge and a range of experts and alumni who consult at government level. Read more

Your programme of study

If you are interested in earth science, and environmental science but you want to specialise in the study of soil specifically the Aberdeen programme gives you in depth knowledge and a range of experts and alumni who consult at government level. Aberdeen is further supported by having the James Hutton Institute within the city limits, a notable institute specialising in soil science over the years known formerly the Macaulay Institute.

Soil Science is becoming increasingly important to our ability to sustain life on earth as we look at how to keep the soil clean from pollutants in water, air and polluting industries, pesticides and all sorts of changes to soil. There are also growing concerns that as the population increases and climate change also increases how do we farm in the future? The degree gives you all the skills and knowledge you need to work as a soil scientist either as a researcher, within government or regulation or as a consultant working with industry and other organisations devoted to soil science.

You learn about soil science, sustainability, land use planning, food security, GIS, and land use with intensive laboratory analysis from one of the top centres in the world for soil science. We also take you into the field to study specific situations and you are guided by our world renowned researchers in the environmental sciences. This is one of only a handful of Soil Science programmes with cutting edge technologies to help you analyse and study soil in depth. Soil science falls within agricultural sciences which were ranked No. 1 in the UK for research excellence (REF 2014) and the highly acclaimed Environmental Science disciplines which Aberdeen has made a name for itself in over the years.

Courses listed for the programme

Semester 1

Core Skills in Environmental Science

Global Soil Geography

Soils for Food Security

Applications for GIS

Semester 2

Environmental Analysis

Land Use and the Changing Environment on Deesside

Optional

Environmental Impact Assessment

Remediation Technology

Catchment Management

Ecological and Environmental Modelling

Semester 3

Project in Soil Science

Find out more detail by visiting the programme web page

https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/304/soil-science/

Why study at Aberdeen?

  • Research at Aberdeen within agricultural and earth sciences is ranked No.1 (REF)
  • You study all methods of analysis and field work to understand the full range of issues within soil and land use which affect the ability to grow crops
  • One of our team developed the award winning 'Cool Farm Tool.' Dr John Hillier developed this to calculate greenhouse gas. The tool is used by known brands such as Marks and Spencer, Costco and Heinz

Where you study

  • University of Aberdeen
  • 12 Months or 24 Months
  • Full Time or Part Time
  • September start

International Student Fees 2017/2018

Find out about fees:

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

*Please be advised that some programmes have different tuition fees from those listed above and that some programmes also have additional costs.

Scholarships

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

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

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

Living in Aberdeen

Find out more about:

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

Find out more about living in Aberdeen:

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

Living costs

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



Read less
The MPhil programmes provide research training, supervision and collaboration to international standards. You can choose a wide range of topics within our marine science research groups. Read more
The MPhil programmes provide research training, supervision and collaboration to international standards. You can choose a wide range of topics within our marine science research groups.

Your research project will be in one of the areas covered by the marine science research groups:

Marine Resources and Renewable Energy (MRRE)
-Antifouling and ballast water treatment
-Bacterial bioactive products
-Bioenergy

Marine Biology, Ecosystems and Governance
-Structural and functional integrity of ecosystems
-Biological and socio-economic drivers of ecosystem change
-Governance and management of resource use

Oceans and Climate focuses on the production, consumption and air-sea exchange of greenhouse gases.

Depending on your previous academic training and the requirements of the project, you receive formal instruction through taught modules in important areas such as laboratory safety and sea survival.

The research community in the School of Marine Science and Technology includes 30 research students, 10-20 MSc students, six to 10 post-doctoral scientists, six technicians and 13 full-time academic staff. This provides you with abundant opportunities to progress your scientific career in any sector. Our research students have been successful at finding work across industry, academia, government agencies and non-governmental organisations.

Delivery

This research degree operates through the Postgraduate Researcher Development Programme (PGRDP). This is part of the Faculty of Science, Agriculture and Engineering (SAgE) Graduate School.

Your original research project is managed in the marine science research groups. There is flexibility in how your research outputs are achieved. Supervisory inputs and collaborations with other schools and faculties are common. Input from outside the University, eg Research Council (RCUK) CASE studentships, is also encouraged.

The programme of work is tailored to your project requirements. You will achieve a certain number of credits through the PGRDP and School in your first two years. You will also:
-Write a thesis for viva voce examination
-Attend regional and international conferences in your chosen subject area
-Prepare papers for publication in academic journals

Work experience

Many research projects include industrial work experience. Other projects involve working with other universities, government institutes and scientific associations. The marine science research groups form part of extensive national and international networks. Recent collaboration includes:
-The Environment Agency
-Natural England
-Northumberland Inshore Fisheries and Conservation Authority
-University of the West Indies (Barbados)
-National Oceanographic Centre Southampton (NOCS)
-University of Costa Rica,
-North Sea Regional Advisory Council
-Haribon Foundation

Read less
Our geochemistry research includes specific areas of expertise. applied and fundamental aspects of geochemistry; environmental sustainability; climate change; and biosphere/geosphere interactions. Read more
Our geochemistry research includes specific areas of expertise: applied and fundamental aspects of geochemistry; environmental sustainability; climate change; and biosphere/geosphere interactions. Through working with academics who are leaders in their field, you will be supported and guided to produce research of an international standard.

The School of Civil Engineering and Geosciences enjoys an international reputation for using the latest science to solve problems of global importance. For geochemistry we have MPhil and PhD supervision in the following areas:

Petroleum-related geological research
-Reservoir and source-rock geochemistry
-Microbial deep biosphere of petroleum reservoirs
-Origin, significance and maturation of molecular biomarker compounds in the sedimentary record
-Physico-chemical properties and behaviour of mudstone sequences
-Shale gas
-Geological sequestration of CO2
-Palynofacies and organic facies of ancient and modern sediments

Environment-related research
-Geomicrobiology
-Mineral science
-Molecular microbial ecology
-Molecular palaeontology
-Soil biogeochemistry
-Waste management
-Bioremediation of polluted soils and waters
-Biogeochemical cycling of elements through Earth history
-Climate change during past greenhouse conditions
-Processes of carbon cycling and export across the land–ocean transition

Delivery

We offer the MPhil and PhD on a full time or part time basis. You will work with research-active academics who will provide advice and support throughout your research project. You will receive formal training in research skills and methods and discipline-specific training is provided where appropriate.

The first three months of study involve intensive theoretical and practical tuition to ensure that you have the study skills to plan your project and can use the equipment and software related to your research. You are encouraged to attend our weekly research seminar series and to present your work at our annual postgraduate research conference, group seminars and relevant international conferences.

Facilities

The School of Civil Engineering and Geosciences has an exceptional range of laboratories equipped with a wide range of analytical instrumentation supporting our research, teaching and contract research projects.
-Chemical and Biological Research Laboratories
-Geotechnics and Structures Research Laboratories

Read less
The course is intended to provide students with a detailed understanding of the sustainability issues associated with Northern European agriculture, and is underpinned by an extensive programme of agri-environment research at Harper Adams. Read more
The course is intended to provide students with a detailed understanding of the sustainability issues associated with Northern European agriculture, and is underpinned by an extensive programme of agri-environment research at Harper Adams.

Having completed the MSc you will be able to identify farming systems and determine their key characteristics, and critically evaluate the environmental impacts of conventional, integrated and organic farming systems. You will also learn to assess and exploit the latest developments in technology, and produce integrated farm management solutions that pay due regard to agronomic, social and environmental requirements.

The course

The continuing production of safe, wholesome food in an environmentally sensitive manner is a major political issue for national governments and internationally within global commodity markets. A report produced by the UK Cabinet Office in 2008 (Food Matters: Towards a Strategy for the 21st Century) predicts that the global population will rise to 9 billion by 2050 rising from a current estimate of nearly 6.8Bn. This increase in population size will substantially increase the demand for food. The global estimates vary in magnitude, but it is thought approximately 25% of crops are lost to pests and diseases, such as insects, fungi and other plant pathogens (FAO Crop Prospects and Food Situation 2009)

In a 2009 response to the emerging issues centred on global food security, the UK BBRSC launched a consultation exercise entitled Future Directions in Research Relating to Food Security. In seeking responses as to the direction of future research BBSRC identified a number of key themes. These included the:
■ Translation of research into commercial practice and the creation of effective partnerships to enable exchange of knowledge and development of skills in the uptake of new scientific findings
■ Establishment of require long-term programmes in research and training, underpinned by investment in the agricultural research infrastructure
■ Focus on applying the latest science to increasing crop and animal productivity globally while minimising negative environmental impact (including reducing greenhouse gas emissions, improving the efficient use of water, energy and other inputs, conserving biodiversity and landscapes), reducing losses from pests and diseases, enhancing food safety and quality for improved nutrition, and reducing waste throughout the food supply chain.

This course is intended to provide students with a key understanding of the issues involved in the sustainable production of food in accordance with the themes outlined above and is underpinned by an extensive programme of associated research at Harper Adams.

How will it benefit me?

The course provides an overview of the key issues involved in sustainable agricultural production within a global context. Since there is a focus on the underlying scientific principles, the course is suited to students of all nationalities in addition to those from the UK. Initially, you will learn to identify global farming systems and determine their key characteristics, before undertaking more complex evaluations of conventional and integrated or organic farming systems. You will undertake training in the use of the latest resources and use these to produce global integrated farm management solutions that pay due regard to agronomic, social, economic and environmental requirements. You will also have the option of undertaking a case study module where you will be able to focus exclusively on farming system of relevance to your background or intended career destination. The research project will provide training in the design, execution, analysis and interpretation of appropriate experiments or surveys to address research questions or problems relevant to sustainable agriculture.

Careers

Students have typically entered a wide variety of professions. Some have worked for government departments and agencies such as Natural England or the Environment Agency. Others have joined agrochemical companies or found positions within agricultural or environmental consultancies.

Read less
Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Power Engineering and Sustainable Energy at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Power Engineering and Sustainable Energy at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

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.



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

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

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

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

Specialist facilities

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

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

Accreditation

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

Course content

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

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

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

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

Want to find out more about your modules?

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

Course structure

Compulsory modules

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

Optional modules

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

For more information on typical modules, read Energy and Environment MSc in the course catalogue

Learning and teaching

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

Assessment

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

Projects

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

Recent research projects by students on this programme have included:

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

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

Career opportunities

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

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

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



Read less
Our International Marine Environmental Consultancy course meets the growing demand for marine consultants and coastal managers in UK, European and international business. Read more
Our International Marine Environmental Consultancy course meets the growing demand for marine consultants and coastal managers in UK, European and international business. You draw on key skills in industry-specific modules, learn to develop the commercial value of your knowledge and enhance your career prospects by working with industry partners on your final project.

The course brings together core ecological skills with the business elements required to compete in this growing sector. Expert academic staff maintain an extensive network of contacts. A four month consultancy project provides opportunities for developing a proposal to collaborate with a world-leading marine consultancy.

This interdisciplinary course attracts a wide range of honours graduates. Your background skills may come from geography, the law and politics as well as marine biology and the environmental sciences. An interest in the marine environment and its management, and a professional, committed attitude are essential.

You will do a research project in one of the areas of the Marine Biology, Ecosystems and Governance (MBEG) research group and key consultancies operating across these areas:
-Structural and functional integrity of ecosystems
-Biological and socio-economic drivers of ecosystem change
-Governance and management of resource use

Opportunities in other marine science research groups may exist:
-Marine Resources and Renewable Energy (MRRE):
-Antifouling and ballast water treatment
-Bacterial bioactive products
-Bioenergy

Oceans and Climate focuses on the production, consumption and air-sea exchange of greenhouse gases.

The marine science research groups form part of extensive national and international networks. Recent partnerships and collaborations include:
-The Environment Agency
-Natural England
-Northumberland Inshore Fisheries and Conservation Authority
-University of the West Indies (Barbados)
-National Oceanographic Centre Southampton (NOCS)
-University of Costa Rica
-North Sea Regional Advisory Council
-Haribon Foundation

You have the support of a marine science research community including 30 research students, six-10 post-doctoral scientists, six technicians and 13 full-time academic staff. This provides you with abundant opportunities to progress your scientific career, whether in industry or academia. Students have been successful at finding employment in industry, academia, government agencies and non-governmental organisations. You will also train to produce final projects of publishable quality.

Delivery

Modules are block taught, with intensive teaching weeks and weeks of private study. Each semester is 60 credits (in full-time mode). The intensive teaching weeks run Monday to Friday from 9am-5pm.

Teaching is delivered via lectures, seminars, practical sessions (in computer labs, on boats and shores) and personal supervision. Projects may be analytical, experimental, or field based, designed to give you the skills you need for future research.

The course finishes with a four month project. This is delivered in conjunction with consultancy partners in the UK or overseas.

Modules are delivered on the University's main campus but the Dove Marine Laboratory and the RV Princess Royal are also used as teaching venues.

Accreditation

Our course is accredited by Institute of Marine Engineering, Science and Technology (IMarEST), the first Institute to bring together marine engineers, scientists and technologists into one international multi-disciplinary professional body.

Our accreditation gives you an additional benchmark of quality to your degree, making you more attractive to graduate employers.

Read less

Show 10 15 30 per page



Cookie Policy    X