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If you are a graduate seeking to enhance your prospects in wastes management or change your career direction, then you should consider this Master’s programme. Read more
If you are a graduate seeking to enhance your prospects in wastes management or change your career direction, then you should consider this Master’s programme. It has been specifically designed to meet the needs and demands of the modern wastes management industry.

The School of Science and Technology at the University of Northampton is a Centre for Excellence in Wastes Management and our MSc course is accredited by the Chartered Institution of Waste Management.

If you do not meet our standard entry requirements, it is possible to undertake a single module and, upon successful completion of this module, progress to the full MSc qualification, contact us at to discuss this option.

Course content

The programme is divided into three stages. To complete the Master’s level qualification you must complete six modules and an independent research thesis to a total of 180 credits. During the course, you complete three compulsory modules and choose three optional modules in stages one and two. Optional modules are subject to staff availability and student interest. Each 20 unit module will be equivalent to 200 hours of study and the module guide, which you will have access to during your studies, has details on how these are allocated. The Research Thesis is worth 60 credits and is therefore equivalent to 600 hours of study.

The research thesis (dissertation) is the final compulsory module in stage three. This ensures that you study the same broad themes within wastes management, but are also able to tailor the focus and level of the qualification to suit your individual needs, experience, interests and career aspirations.

You can also take certain modules as a ‘one off’, either as a taster before deciding whether to study the course in full, or as an opportunity to update your skills in a particular area.

Professional Membership

As a CIWM Accredited Course, students studying wastes management are entitled to 12 months free student membership of the CIWM.

Benefits of membership include:
-Free copy of CIWM Journal delivered on your doorstep each month.
-Free weekly email news service, News Online, delivered to your Inbox.
-Discounted rates on annual conference, training courses and seminars.
-Networking opportunities through CIWM Regional Centres.
-Access to CIWM NGG (New Generation Group) events.
-Free technical advice and use of CIWM Library Services.
-Professional and career development.

Careers

The growing worldwide awareness and significance of environmental management, wastes minimisation and pollution control, coupled with recent legislative changes in many countries have resulted in an explosion of exciting job opportunities in the wastes industry. Consequently, there is now a strong demand for wastes management graduates. There are opportunities in industry, local and national authorities, as well as within the specialist wastes management industry. Students from this course have also gone on to MPhil and PhD studies at the University of Northampton.

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
Accredited by the Chartered Institution of Wastes Management, the programme prepares you for a career in the growing environmental and clean technologies sector, where there is increasing global demand for skilled graduates. Read more
Accredited by the Chartered Institution of Wastes Management, the programme prepares you for a career in the growing environmental and clean technologies sector, where there is increasing global demand for skilled graduates.

About the programme

The global market in environmental goods and services is currently worth about £3 trillion. Global investment attracted by ‘green technologies’ for electrical power generation recently exceeded that for coal and natural gas. This area is being actively promoted in the UK and Scottish context for economic development.

The programme develops core skills in environmental management, coupled with an understanding of technologies that enhance the
sustainable use of natural resources and minimise the environmental impact of economic activities, exploiting value from industrial process by-products and waste materials.

Our research-active academics are experienced in projects monitoring and assessing environmental impacts, developing innovative treatment technologies and working with industry and business. We have also been involved in support for and development of environmental policy and regulation in the UK, the EU and internationally.

Your learning

The Postgraduate Diploma comprises six taught modules. All MSc candidates undertake a research project/dissertation in Trimester 3.
Subjects include:
• Environmental Systems
• Sustainable Environmental Management
• Concepts and Tools in Environmental Technology
• Pollution Control
• Waste Management Techniques
• Process Principles for Clean Technologies

MSc

You will also undertake a Waste Masters dissertation.

Our Careers Adviser says

Graduates build careers across all industrial sectors and within both public and private sectors dealing with environment, pollution
control, waste management, regulation and enforcement in the emerging technologies to improve environmental performance. This includes process based operations as well as management, audit and impact assessment.

Professional recognition

Once enrolled, students can apply to the Chartered Institution of Wastes Management (CIWM) to become a Student Member. When the programme is completed students can apply to CIWM to become a Graduate Member and use the designatory letters Grad MCIWM.

Note: To obtain the MSc, students will usually take 9 months to gain the Postgraduate Diploma and then normally an additional 3 months of study to gain the MSc, from the date of commencement of the project.

February entry may be possible – applicants should consult with the Admissions Officer.

First-class facilities

Get the hands on experience you need to succeed. We have excellent specialist facilities which support our research students and staff. These include an advanced chemical analysis lab: with state-of-theart chemical analysis for isotopic and elemental analysis at trace concentrations using ICPMS/OES and the identification of organic compounds using LCMS; and the Spatial and Pattern Analysis (SPAR) lab: providing high specification workstations, geographical information system (GIS) software, geochemical and image processing facilities to support data management in science research.

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This course will explore methods of managing wastes alongside the conversion of wastes to energy and the role of energy from waste in the UK, in terms of the technology and the biochemistry and/or chemistry of fuels. Read more
This course will explore methods of managing wastes alongside the conversion of wastes to energy and the role of energy from waste in the UK, in terms of the technology and the biochemistry and/or chemistry of fuels. As such this course is targeted at engineering and physical science graduates due to the nature of the modules. Students completing this course will gain a broad appreciation of the technical, economic and environmental challenges that face the energy from waste industry. It is anticipated that students completing this course will be employed by waste management companies, energy companies and the engineering sector dealing with waste, in both technical and engineering consultancy along with management roles across the sector.

Read less
The Energy and Environmental Management postgraduate course allows you to gain an MSc, PGCert or PGDip awards. The course provides a broad and comprehensive introduction to energy and environmental management. Read more
The Energy and Environmental Management postgraduate course allows you to gain an MSc, PGCert or PGDip awards. The course provides a broad and comprehensive introduction to energy and environmental management. A critical approach to theories, techniques and methods in energy and environmental management is developed and provides you with a learning environment in which you will develop a capacity for independent study, an ability to collaborate with others in team settings, and a capacity for critical thought and reflection.

Several modules on the Energy and Environmental Management postgraduate course are currently accredited by the Chartered Institution of Wastes Management. UCLan also intend to gain accreditation from the Chartered Institution of Water and Environmental Management and the Energy Institute.

INDUSTRY LINKS

Several modules (Environmental Management within Organisations, Global Waste Management and the Dissertation) are currently accredited by the Chartered Institution of Wastes Management. It is expected that accreditation will also be sought from the Chartered Institution of Water and Environmental Management and the Energy Institute.

LEARNING ENVIRONMENT AND ASSESSMENT

A combination of both coursework and on-line exercises. The coursework types include the following: technical reports, case studies essays, presentations, group work, on-line forum activity and academic posters.

OPPORTUNITIES

Careers are developed throughout carbon/energy and environmental management industries. Recent employers include consultancy firms, local government, NGOs, Corporate organisations and the Environment Agency. This strong employment record underlines the School's philosophy in delivering programmes of a high quality.

FURTHER INFORMATION

This course provides an education in the emerging environmental field of energy management, which is linked with organisations looking to employ energy and environmental managers. Energy is becoming a global issue and international development is linked to the economics of natural resources. The public and private sectors, not just those associated with energy management, require staff with a detailed environmental knowledge at a regional, national and international scale. Businesses are increasingly looking outside Europe to Asia, Australasia and the Americas to inform their best practices and maintain market share.

This course provides a critical approach to theories, techniques and methods in energy and environmental management.

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If you are a scientist or technologist wanting transition into an industry with exciting career opportunities or are already involved in the leather industry but wanting to increase your knowledge and skills, this is an ideal course for you. Read more
If you are a scientist or technologist wanting transition into an industry with exciting career opportunities or are already involved in the leather industry but wanting to increase your knowledge and skills, this is an ideal course for you.

Here at the Institute for Creative Leather Technologies (ICLT), you will cover the science and technology of leather manufacture in a way designed to suit graduates for senior tannery positions. Whilst developing the critical mind it provides an excellent base for a move into Research and Development departments within chemical companies, tanneries and brands or into academic careers.

Leather is returning to prominence as nearly all alternatives require using up non-renewable carbon-based materials. Scientific advances in conjunction with environmental responsibility have transformed the leather manufacture industry into a modern scientific process, creating a highly sustainable material with high value in many sectors such as sports, automobiles, luxury goods and fashion.

Northampton graduates have been at the forefront of these changes making our leather alumni one of the best bodies in the industry to be associated with. Successful graduates from this course can expect easy access into senior industry positions.

This course is ideal for embedding into corporate continuing personal development (CPD) programmes. Taking this into account, ICLT delivers the course in a way that enables employees to only be away from their place of work for three months between September and December. During this period the theoretical and practical elements of the course are delivered in an intensive manner, after which the employees are able to return to their workplace to continue with their assessments and research elements of the programme. The course also enables students to study in the traditional manner where they stay at University for the whole academic year if desired.

As one of the foremost centres for leather education in the world, ICLT is dedicated to providing cutting edge education and training in the theory and practice of leather technology at the highest level.

If you do not meet our standard entry requirements, it is possible to undertake a single or a number of modules. The non-credit bearing course is called ‘Professional Leather Development’ Course, for further information about this course please visit the Professional Leather Development Course page: https://www.northampton.ac.uk/study/courses/professional-leather-development-course/

Course content

The MSc Leather Technology (Professional) course is unique in that it aims to provide the opportunity to acquire and/or enhance technical skills within the subject of leather technology. Students will study within an environment that encourages the development of intellectual creativity as well as providing transferable skills to undertake research with respect to advanced technologies, developing skills and flexibility necessary to discriminate between technical and entrepreneurial issues and relating these to the needs of the leather industry such as successful management of the commercial operations.

This course offers students the opportunity to work and learn in a state-of-the-art teaching tannery for some of the modules, and will also be working with staff with a mix of academic and industrial experience. Many of the staff carry out research in various leather subjects and over the last 20 years Northampton leather research has built a leading world-wide reputation.

Industry leaders are frequent visitors to meet students and provide knowledge on current technical and commercial aspects of leather and its fascinating chain from farm to fashion or one of its many other end uses.

The MSc Leather Technology (Professional) course is delivered to meet student flexibility. In order for you to complete Master’s level qualification, you must complete up to seven modules and an independent research dissertation. During the course, you will complete six compulsory modules and choose up to two optional modules. This ensures that you have a basic understanding of principles pertinent to the leather industry with an added advantage in that you are able tailor the course to meet your particular needs and career aspirations.

Further information on the indicative content of the leather modules is available through the module catalogue for Leather Technology (Level 7).

Course modules (16/17)

-Leather Process Operations
-Performance Leather Process Operations
-Quality Evaluation and Systematic Problem Solving
-Sustainable Manufacture within the Leather Industry
-Research and Analytical Methods
-Dissertation
-From Hide to High Street
-Leather Science
-Marketing: Principles and Management
-International Marketing Strategy
-Managing Operations
-Podiatry: Applied to the Footwear Industry
-Wastes Management

Methods of Learning

Theoretical lectures and seminars are reinforced by practical examples, case studies and site visits. Our virtual learning environment allows you and course tutors to exchange ideas as well as submit assignments.

Assessments

A variety of approaches to teaching is used such as lectures, seminars, workshops, practical sessions with course teaching materials made available through our virtual learning environment. Modules are assessed by a wide range of methods and include the following: practical reports, seminar files, reflective portfolios, presentations and dissertation.

Facilities and Special Features

As the UK’s only university to integrate leather technology with subjects such as fashion, marketing, business and the environment, we are proud to house an on campus working tannery for practical leather making as well as laboratories to enable leather testing.
-100% employment of graduates in 2011, 2012, 2013, 2014.
-This course is unique to the University of Northampton and not offered anywhere else in the UK or Europe.
-The University has an on campus tannery and laboratories for teaching.
-Modules to cater for leather career choices in practical leather making and testing.
-Industry-led practical workshops and seminars in technology and supply chain knowledge delivered by international experts.
-Continual networking with potential employers within the industry.
-Opportunities to attend international leather fairs in Hong Kong, Milan and Shanghai.
-Bursaries and scholarships available for leather students.

Careers

Graduates of this course are in high demand and are able to secure suitable posts in leather making or associated industries, including technical management, research and development, technical services, higher education and government bodies. When it comes to jobs in the leather industry, demand exceeds supply and opportunities are available worldwide with excellent progression prospects. Employment opportunities can also be found in other materials production or chemical industries. Successful graduates from this course can also proceed to undertake MPhil or PhD studies with us.

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The course is based in the Sustainable Environment Research Centre (SERC) a leading and internationally recognised centre for over 30 years. Read more
The course is based in the Sustainable Environment Research Centre (SERC) a leading and internationally recognised centre for over 30 years. SERC is home to The Wales Centre of Excellence for Anaerobic Digestion and the University of South Wales Centre for Renewable Hydrogen Research and Demonstration,

The UK Governments Low Carbon Transition Plan details how the Government plans to meet its 2020 GHG emissions targets. It predicts that as a result of its actions that 1.2 million green jobs will be created and 40% of electricity production will be from low carbon resources. It is predicted that £110bn of investment will be necessary to meet the targets as currently set out. The picture is similar across the EU and the rest of the world. There is a significant need for individuals with the expertise necessary to help meet those targets.

This MSc in Renewable Energy and Resource Management will provide the wealth of knowledge and skills needed for employment in a range of public and fast-growing commercial green sector roles. Your studies will increase your knowledge and understanding of the generation and provision of renewable energy, hydrogen, water, wastewater treatment and solid wastes management. You will become familiar with the impact of policy and legislation, renewable energy technologies, waste management hierarchy and techniques, and water and wastewater treatment. You will also train in relevant computing software, and analytical and monitoring equipment used by industry.

See the website http://courses.southwales.ac.uk/courses/374-msc-renewable-energy-and-resource-management

What you will study

Students will study the following taught modules:
- Renewable Energy I & Hydro, Tidal, Wave, and Bio-energy
- Renewable Energy II & Wind, Solar, and Geothermal
- Solids Resource Management
- Water and Wastewater Treatment Processes

Plus 2 from the following optional modules:
- Hydrogen& Fuel Vector for the Future
- Energy and Environmental Legislation and Policy
- Advanced Materials for Energy Applications
- Anaerobic Treatment Processes
- Analytical Science and the Environment

You will also complete a substantial project, usually in conjunction with industry, energy/environmental consultancy firms, governmental regulatory agencies, local authorities or within our Sustainable Environment Research Centre.

The subjects taught within the MSc are underpinned by high quality research which was rated as being mainly internationally excellent or world leading in RAE 2008. This included research in hydrogen energy, bio-energy, anaerobic digestion, process monitoring and control, combustion processes, and waste and wastewater treatment systems.

Learning and teaching methods

Full-time students spend about 12 hours in lectures, seminars, tutorials, and computing and laboratory-based practical sessions each week, plus research and background reading. We have an exciting programme of site visits and fieldwork trips.

Work Experience and Employment Prospects

This MSc is designed to develop cutting-edge knowledge and high-level practical skills relevant to many areas of postgraduate employment, particularly managerial, regulatory, scientific and technological roles related to energy and the environment. These include local authorities, government regulatory agencies, manufacturing industries, energy and environmental consultancy companies, waste management companies, water companies, environmental and energy advice centres, research centres, academia, and national and international non-governmental organisations.

Assessment methods

The taught modules are assessed by a mixture of coursework and examinations. The project is assessed by a written dissertation and an oral examination (viva voce).

Coursework involves individual and group mini-projects, fieldwork and visit reports, and poster and oral presentations. Part-time students attend generally one day per week, plus visits and fieldwork.

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This full time 12 month intensive programme is designed to provide advanced specialised training for earth science graduates, leading to excellent employment opportunities in the extractive industry. Read more
This full time 12 month intensive programme is designed to provide advanced specialised training for earth science graduates, leading to excellent employment opportunities in the extractive industry. It is suitable for those who already have an honours degree in geology, mining/minerals engineering or a related subject.

You will attain a comprehensive understanding of the role of a geoscientist working in the mining industry. New skills include underground geological and geotechnical mapping, surveying, mineral exploration, ore microscopy, ore deposit modelling and mine planning. In-depth coverage of mineral resource estimation and grade control, mineral extraction and management, mining law and the environmental impact of mining, enable skills in quantifying the economic value of an ore body and assessing its potential for exploitation to be attained. There is emphasis on acquiring knowledge of the geological characteristics and genesis, methods of exploration, extraction and processing techniques of the major types of metalliferous ore deposit, bulk commodities and industrial minerals.

Taught modules are presented over two semesters and individual projects are undertaken throughout the summer vacation, often as industrial placements with a mining/exploration company. Recent projects have been carried out in all major mining countries on six continents, including Australia, Tanzania, Mongolia, Chile as well as in the UK.

Programme Structure

You will study 180 credits to obtain an MSc and 120 credits for a PgDip

Compulsory modules

The compulsory modules can include; Research Project and Dissertation; Resource Estimation; Ore Deposit Geology and Industrial Minerals; Techniques in Mining Geology ; Excavation and Geomechanics ; Economics, Processing & Environment

Optional modules

Some examples of the optional modules are; Advanced Techniques for Mineral Analysis and Mine Wastes: Principles, Monitoring and Remediation.

The modules listed here provide examples of what you can expect to learn on this degree course based on recent academic teaching. The precise modules available to you in future years may vary depending on staff availability and research interests, new topics of study, timetabling and student demand

Learning and teaching

Formal teaching ends in late April/May with a field excursion to examine the geology and visit mines in an area of the world famous for its mining activity. Extensive use is made of Camborne School of Mines' underground mine facilities, laboratories, mineral processing pilot plant, and the superb field geology and extractive industry operations in South West England.

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This programme is taught at the Penryn Campus near Falmouth. Read more
This programme is taught at the Penryn Campus near Falmouth.

It is a full-time one-year programme to enable graduates in geography, earth sciences, economics and engineering to train as professional surveyors who have knowledge both of modern land surveying techniques and the principles and application of land and environmental management. Graduate destination statistics show more than 90% of students obtaining related employment.

The programme introduces and develops surveying practice through a module that stretches over both semesters. Other modules provide training in land management, planning, general management and environmental control. In Easter there is a fieldtrip where both the surveying skills and environmental/land management knowledge are put to the test as a major case-study. The final part of the programme is a dissertation that can form part of an industrial partnership. The programme is accredited by both the Royal Institute of Chartered Surveyors (RICS) and the Institute of Civil Engineering Surveyors (ICES).

Programme Structure

You can either study the course full time over a year or part-time over 3 years.

Compulsory modules

The compulsory modules can include; Professional Development; Health and Safety in the Extractive Industry; Land Surveying; Project Management; Advanced Surveying; Mine Wastes: Principles, Monitoring and Remediation; GIS For Surveyors; Law for Surveyors; Land Management; and Project and Dissertation

The modules listed here provide examples of what you can expect to learn on this degree course based on recent academic teaching. The precise modules available to you in future years may vary depending on staff availability and research interests, new topics of study, timetabling and student demand.

A research- and practice-led culture

We believe every student benefits from being taught by experts active in research and practice. You will discuss the very latest ideas, research discoveries and new technologies in seminars and in the field and you will become actively involved in a research project yourself. All our academic staff are active in internationally-recognised scientific research across a wide range of topics. You will also be taught by leading industry practitioners.

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This programme is ideal for engineers and scientists who want to improve the delivery of water and sanitation services in low- and middle-income countries. Read more
This programme is ideal for engineers and scientists who want to improve the delivery of water and sanitation services in low- and middle-income countries. You will develop knowledge, expertise and skills in many aspects of inclusive and sustainable public health infrastructure and services.

The programme is based in the School of Civil and Building Engineering’s Water, Engineering and Development Centre (WEDC), one of the world’s leading education and research institutes of its kind.

Modules are taught by experts in a broad range of disciplines who have considerable experience of working in low- and middle- income countries. Classes include a mix of nationalities and past experiences, providing both a stimulating learning experience and a valuable future network.

Externally accredited, WEDC programmes are well-established, and held in high regard by practitioners and employers from both the emergency and development sectors.

Key Facts

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

- An outstanding place to study. The School of Civil and Building Engineering is ranked in the UK top 10 in the Guardian Good University Guide

- Excellent graduate prospects. Many of our graduates are employed by relief and development agencies.

- Professionally accredited. The Chartered Institution of Water and Environmental Management (CIWEM) have accredited this programme. Students registered for this programme are eligible for free student membership of CIWEM. The Joint Board of Moderators (JBM) has also accredited all WEDC MSc degrees as meeting requirements for Further Learning.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/water-waste/

Programme modules

Core modules:
- Water and Waste Engineering Principles
The aims of this module are for the student to understand the range of suitable technologies for water supply and engineering management of liquid and solid wastes in low- and middle-income countries.

- Management of Water and Sanitation
The aim of this module is to introduce the principles, concepts and key issues of managing sustainable water and environmental sanitation services for low-income consumers in developing countries.

- Water Utilities Management
The aim of this module is to better enable participants to plan for and manage urban water and sanitation services in developing countries.

- Data Collection, Analysis and Research
The aims of this module are to introduce the principles and approaches for doing research and studies on infrastructure and services in low- and middle-income countries and to prepare students to undertake the research dissertation module.

- Group Project
The aims of this module are for the student to work within a group to understand the necessary inter-relationships between different components of their programme of study; to consolidate and integrate material contained in earlier taught modules; and to learn how to work as part of a team.

- Research Dissertation
The aim of this module is to provide the student with experience of the process and methodology of research by defining and studying (on an individual basis) a complex problem in a specialised area relating to their degree.

Optional Modules (choose 3):
- Water Source Development
The aim of this module is for the student to understand the occurrence, location, exploration, exploitation and pollution of groundwater and surface water sources.

- Wastewater Treatment
The aims of this module are for the student to understand the various stages, and unit operation and process options, for treatment of wastewaters, particularly in low- and middle-income countries; and to understand the principles for planning and design of wastewater treatment facilities, particularly in low- and middle-income countries.

- Integrated Water Resources Management
The aim of this module is for participants to understand the concepts used in integrated planning and management of water resources in low and middle-income countries.

- Solid Waste Management
The aim of this module is to introduce participants with available and possible options in solid waste management for low and middle income countries. To make participants familiar with the key issues for low income countries.

- Water Distribution and Drainage Systems
The aim of this module is for the student to understand the most important aspects of how to design, construct and maintain piped water distribution, drainage and sewerage systems.

- Short Project
The aim of this module is for participants to be able to undertake extended study of a subject of their own choosing which is related to their Postgraduate Programme to enable them to conduct an independent review and analysis to understand state of art issues or a topic.

Facilities

All masters students have access to our excellent laboratory facilities which include equipment for field sampling and analysis of water and wastewater, and some of the largest hydraulics equipment in the UK. There are three dedicated water laboratory staff available to help you use our equipment who are specialists in pollutant analysis, hydraulics and running continuous trials.

Practical training includes:
- Hand-pump maintenance using the largest single site collection of hand-pumps;
- latrine slab construction;
- flow measurements; and
- water quality sampling and analysis.

Field visits are made to relevant UK facilities.

WEDC has a unique sector Resource Centre with a dedicated and skilled information officer. Over 19,000 items can be searched on a customized database allowing ready access to this collection of books, series, country files, student projects, videos, journals, maps, and manufacturers' catalogues.

The Resource Centre also provides a dedicated quiet study space for WEDC students. Many items including all WEDC publications and over 2500 papers presented at 37 WEDC International Conferences are available in the open access sector knowledge base.

How you will learn

The programme comprises both compulsory core modules and optional modules which may be selected. A group case study module draws together material from across the programme and develops team working skills. The individual research project and dissertation (frequently linked to specific needs of an agency) of between 75 and 150 pages in length concludes the programme. To support your learning you will have access to our comprehensive facilities including laboratories, hand-pumps, and a dedicated Resource Centre.

- Assessment
For most modules, students are assessed by one item of coursework (two items for foundation modules) and an in-class test. The Group Project module is assessed on the basis of written documents and spoken presentations, including an individual component for the module mark. The individual Research Dissertation is assessed on the basis of a written dissertation, and this module includes an oral when a student discusses their submitted dissertation with their supervisor and a second member of academic staff.

Careers and further study

Many WEDC students and alumni work for international NGOs (MSF, Oxfam, SCF, GOAL, WaterAid, etc.) and agencies (such as UNICEF), or National Governments. Graduate job titles include Sanitation Technical Manager, Water and Sanitation Consultant, Project Manager, Environmental Engineering Consultant and Civil Engineering Specialist.

Scholarships / Bursaries

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

Why choose civil engineering at Loughborough?

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

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

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

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

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

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

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/water-waste/

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