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Masters Degrees (Sustainability Engineering)

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Degree. Master of Science with a major in Energy and Environmental Engineering. The Sustainability Engineering and Management master’s programme deals with the multifaceted challenge of developing products, services and technical systems that contribute to increased resource-effectiveness and sustainability. Read more

Degree: Master of Science with a major in Energy and Environmental Engineering

The Sustainability Engineering and Management master’s programme deals with the multifaceted challenge of developing products, services and technical systems that contribute to increased resource-effectiveness and sustainability.

It is well-known that economic development and human welfare depend on the availability of raw materials and energy. However, the exploitation of such natural resources has many environmental implications such as climate change, resource scarcity and the uncontrolled dispersal of hazardous substances. In times of global environmental problems and concerns about the long-term availability of natural resources such as metals and minerals, incentives for using materials and energy in more intelligent and efficient ways are increasing among governments, companies and other organisations.

McKinsey, one of the largest management consultancy firms in the world, has emphasised the urgent need for a resource revolution. The aim is to address the anticipated economic and political implications of resource scarcity, steadily increasing pollution levels from primary production and the uneven distribution of natural resources among regions. Companies are thus facing the challenge of delivering increasing amounts of products and services, while at the same time preventing the depletion of natural resources, cutting costs and contributing to a sustainable society.

Combined research perspectives

This master’s programme offers a unique knowledge profile and aims to train future engineers who can contribute to such a societal transition towards the more efficient use of natural resources. More specifically, you will learn how to combine a multidisciplinary system perspective with skills in modern environmental and energy engineering. With this proactive and holistic approach, environmental problems can often be significantly limited or prevented, without jeopardising human well-being.

The programme combines the perspectives of two research groups – Energy Systems and Environmental Technology and Management – at the Department of Management and Engineering. These groups deal with system solutions and state-of-the-art research in areas like renewable energy and biofuels, energy efficiency, waste management, urban and landfill mining, corporate environmental management and integrated product-service offerings. Several renewable energy solutions have already been implemented in the region, which means that you will have the opportunity to see how such environmental technology works in practice. Moreover, there is a national research excellence centre on biogas production and utilisation located at the university, which involves a wide network of academic, industry-related and public actors.

Innovation courses included

The first semester features introductory courses in environmental engineering and energy systems, and courses in traditional engineering topics such as product development and project management. The second and third semesters involve specialisation in concepts, strategies and methods for achieving more efficient use of materials and energy, at business, inter-business and societal levels. These semesters also include courses on the development and implementation of sustainability concepts and strategies such as innovative entrepreneurship and innovation management.

Examples of courses within the programme are: Energy Systems, Large Technical Systems and the Environment, Energy Systems Analysis, Innovative Entrepreneurship, Biofuels for Transportation, Industrial Ecology, Management Systems and Sustainability, Innovation Management and Resource-Efficient Products.

The programme concludes with a degree project (30 ECTS) in the final semester.



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This Masters in Sustainable Engineering will let you assess sustainability issues and formulate strategies to implement practical solutions in business and society. Read more

This Masters in Sustainable Engineering will let you assess sustainability issues and formulate strategies to implement practical solutions in business and society. The course aims to produce Sustainability Engineers who can make optimum use of energy and materials – embracing concepts such as life-cycle analysis and recycling within the design process.

The course has been developed together with industry and covers a practical framework to meet the challenge of responsibly using the world’s finite natural resources. This includes narrowing the ‘sustainable gap’ and developing an awareness of environmental degradation.

As part of the Masters in Sustainable Engineering dissertation, you’ll undertake ‘in-house’ laboratory-based projects. You’ll also be able to take environmental management system assessments or technical design analyses within companies too. These include William Grant & Sons, Caledonian Alloys, United Wire Ltd, and the Scottish Environmental Protection Agency.



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The global shortage of qualified civil engineers includes specialists in water engineering and this MSc programme helps redress this imbalance by providing graduates with an advanced knowledge and skill base to equip them for senior industry roles. Read more

About the course

The global shortage of qualified civil engineers includes specialists in water engineering and this MSc programme helps redress this imbalance by providing graduates with an advanced knowledge and skill base to equip them for senior industry roles.

Brunel’s MSc in Water Engineering is unique in providing specialist knowledge on the critical sub-topics of water and wastewater management and engineering, desalination systems, building water services engineering, industrial waste water management, and water in health care.

The programme demonstrates the links between theory and practice by including input from our industrial partners and through site visits. This is a key aspect for establishing a competitive and high added value course that provides adequate links with industry.

Features of the course include:

Students’ skills in gathering and understanding complex information from a variety of sources (including engineering, scientific and socio-economic information) will be developed in an advanced research methods module. 

Issues relating to risk and health and safety will be introduced in the research methods module and built on in specialist modules. 

Generic modules in financial and project management will underpin specialist modules focusing on water engineering topics.

Real problem-solving examples – starting from basic principles, to the identified problem, the solution, the implementation process and was implemented and the end result. 

Real case studies – demonstrating how environmental and economic sustainability is considered within civil engineering, particularly in water resources management.

Aims

Problems associated with water resources, access, distribution and quality are amongst the most important global issues in this century. Water quality and scarcity issues are being exacerbated by rising populations, economic growth and climate change*.

Brunel's programme in Water Engineering aims to develop world class and leading edge experts on water sustainability who are able to tackle the industry’s complex challenges at a senior level. During the programme you will also learn about the development and application of models that estimate the carbon and water footprint within the energy and food sector.

The MSc is delivered by experienced industry professionals who bring significant practical experience to the course – and the University’s complete suite of engineering facilities and world-class research experience are set up for development and engineering of advanced systems, testing a variety of processes, designs and software tools.

*Recent figures indicate that 1.1 billion people worldwide do not have access to clean drinking water, while 2.6 billion do not have adequate sanitation (source: WHO/UNICEF 2005). 

Course Content

The primary aim of this programme is to create master’s degree graduates with qualities and transferable skills for demanding employment in the water engineering sector. Graduates will have the independent learning ability required for continuing professional development and acquiring new skills at the highest level.

Specific aims are as follows:

- To provide education at postgraduate level in civil engineering. 
- To develop the versatility and depth to deal with new, complex and unusual challenges across a range of water engineering issues, drawing on an understanding of all aspects of water engineering principles. 
- To develop imagination, initiative and creativity to enable graduates to follow a successful engineering career with national and international companies and organisations. 
- To provide a pathway that will prepare graduates for successful careers including, where appropriate, progression to Chartered Engineer status.

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

Knowledge and understanding of:

- The principles of water engineering, including fluid mechanics, hydrology, and sustainable design. 
- Specialist areas that impact on the successful application of water engineering knowledge projects, e.g. sustainable construction management, financial management and risk analysis. 
- The interplay between engineering and sustainability in complex, real-world situations.

At the cognitive level students will be able to:

- Select, use and evaluate appropriate investigative techniques.
- Assemble and critically analyse relevant primary and secondary data.
- Recognise and assess the problems and critically evaluate solutions to challenges in managing water engineering projects.
- Evaluate the environmental and financial sustainability of current and potential civil engineering activities.

Personal and transferable skills that students develop will allow them to:

- Define and organise a substantial advanced investigation. 
- Select and employ appropriate advanced research methods. 
- Organise technical information into a concise, coherent document.
- Effectively employ a variety of communication styles aimed at different audiences. 
- Plan, manage, evaluate and orally-presented personal projects. 
- Work as part of, and lead, a team.

Typical Modules

Each taught module will count for 15 credits, approximating to 150 learning hours. The Master's programme can be taken full time, over 12 months. The first eight months of the full time course will eight taught modules. For the final four months, students will complete a dissertation counting for 60 credits. Modules cover:

Sustainable Project Management
GIS and Data Analysis
Water Infrastructure Engineering
Risk and Financial Management
Hydrology & Hydraulics
Water Treatment Engineering
Water Process Engineering
Research Methods
Civil Engineering Dissertation

Teaching

Our philosophy is to underpin theoretical aspects of the subject with hands-on experience in applying water engineering techniques. Although you may move on to project management and supervision roles, we feel it important that your knowledge is firmly based on an understanding of how things are done. To this end, industrial partners will provide guest lectures on specialist topics.

In addition to teaching, water engineering staff at Brunel are active researchers. This keeps us at the cutting edge of developments and, we hope, allows us to pass on our enthusiasm for the subject.

How many hours of study are involved?

Contact between students and academic staff is relatively high at around 20 hours per week to assist you in adjusting to university life. As the course progresses the number of contact hours is steadily reduced as you undertake more project-based work.

How will I be taught?

Lectures:
These provide a broad overview of the main concepts and ideas you need to understand and give you a framework on which to expand your knowledge by private study.
Laboratories:
Practicals are generally two- or three-hour sessions in which you can practise your observational and analytical skills, and develop a deeper understanding of theoretical concepts.
Design Studios:
In a studio you will work on individual and group projects with guidance from members of staff. You may be required to produce a design or develop a solution to an engineering problem. These sessions allow you to develop your intellectual ability and practice your teamwork skills.
Site visits:
Learning from real-world examples in an important part of the course. You will visit sites featuring a range of water engineering approaches and asked to evaluate what you see.
One-to-one:
On registration for the course you will be allocated a personal tutor who will be available to provide academic and pastoral support during your time at university. You will get one-to-one supervision on all project work.

Assessment

Several methods of assessment are employed on the course. There are written examinations and coursework. You will undertake projects, assignments, essays, laboratory work and short tests.

Project work is commonplace and is usually completed in groups to imitate the everyday experience in an engineering firm, where specialists must pool their talents to design a solution to a problem.

In this situation you can develop your management and leadership skills and ensure that all members of the group deliver their best. Group members share the mark gained, so it is up to each individual to get the most out of everyone else.

Special Features

Extensive facilities
Students can make the most of laboratory facilities which are extensive, modern and well equipped. We have recently made a major investment in our Joseph Bazalgette Laboratories which includes hydraulic testing laboratory equipment and facilities such as our open channel flow flumes.

Personal tutors
Although we recruit a large number of highly qualified students to our undergraduate, postgraduate and research degrees each year, we don’t forget that you are an individual. From the beginning of your time here, you are allocated a personal tutor who will guide you through academic and pastoral issues.

World-class research
The College is 'research intensive' – most of our academics are actively involved in cutting-edge research. Much of this research is undertaken with collaborators outside the University, including construction companies, water utilities, and other leading industrial firms. We work with universities in China, Poland, Egypt, Turkey, Italy, Denmark and Japan. This research is fed directly into our courses, providing a challenging investigative culture and ensuring that you are exposed to up-to-date and relevant material throughout your time at Brunel.

Strong industry links
We have excellent links with business and industry in the UK and overseas. This means:
Your degree is designed to meet the needs of industry and the marketplace.
The latest developments in the commercial world feed into your course.
You have greater choice and quality of professional placements.
We have more contacts to help you find a job when you graduate.

Visting Professors 
The Royal Academy of Engineering - UK’s national academy for engineering has appointed senior industrial engineers as visiting professors at Brunel University London.
The Visting Professors Scheme provides financial support for experienced industrial engineers to deliver face-to-face teaching and mentoring at a host of institutions. Our engineering undergraduates will benefit from an enhanced understanding of the role of engineering and the way it is practised, along with its challenges and demands. 

Women in Engineering and Computing Programme

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

Accreditation

This course has been designed in close consultation with the industry and is accredited as a designated 'technical' MSc degree by the Join Board of Moderators (JBM). The JBM is made up of Institution of Highways and Transport and the Institution of Highway Engineeres respectively.

1. This means this course provides Further Learning for a Chartered Engineer who holds a CEng accredited first degree (full JBM listing of accredited degrees).
2. As a designated ‘technical’ MSc, it will also allow suitable holders of an IEng accredited first degree to meet the educational base for a Chartered Engineer.

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You can access six study streams on this Masters programme. Bridge Engineering. Construction Management. Geotechnical Engineering. Read more

You can access six study streams on this Masters programme:

  • Bridge Engineering
  • Construction Management
  • Geotechnical Engineering
  • Structural Engineering
  • Water Engineering and Environmental Engineering
  • Infrastructure Engineering and Management

As well as supporting the career development of Civil Engineering graduates, this programme provides the necessary further learning for engineers working in the construction industry who hold related first degrees such as engineering geology or construction management.

It is also designed to update the technical skills of practising engineers engaged in the planning, design, construction and operation of civil-engineering works.

Programme structure

This programme is studied full-time over one academic year and part-time / distance learning for between two to five academic years. It consists of eight taught modules and a dissertation.

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

Example module listing

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

Structural Engineering Group Modules

Bridge Engineering Group Modules

Geotechnical Engineering Group Modules

Construction Management Group Modules

Infrastructure Engineering Group Modules

Water and Environmental Engineering Group Modules

Dissertation

Educational aims of the programme

  • The Civil Engineering programme aims to provide graduate engineers with:
  • Advanced capabilities and in-depth knowledge in a range of specialised aspects of civil engineering
  • It is also designed to update the technical skills of practising engineers engaged in the planning, design, construction and operation of civil engineering works and to contribute to a personal professional development programme
  • A working knowledge of some of the UK and European standards and codes of practice associated with the design, analysis and construction of civil engineering structures and the ability to interpret and apply these to both familiar and unfamiliar problems
  • The necessary further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer in both a technical or non-technical capacity dependent upon module selection

Programme learning outcomes

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

Knowledge and understanding

  • The mathematical principles necessary to underpin their education in civil engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of multi-disciplinary open ended engineering problems
  • The properties, behaviour and use of relevant materials
  • The management techniques which may be used to achieve civil engineering objectives within that context
  • Some of the roles of management techniques and codes of practice in design
  • The principles and implementation of some advanced design and management techniques specific to civil engineering
  • Mathematical and computer models relevant to civil engineering, and an appreciation of their limitations
  • The role of the professional engineer in society, including health, safety, environmental, sustainability, ethical issues and risk assessment within civil engineering
  • The wider multidisciplinary engineering context and its underlying principles
  • Developing technologies related to civil engineering and the ability to develop an ability to synthesize and critically appraise some of them
  • The framework of relevant requirements governing engineering activities, including personnel, health, safety, and risk issues (an awareness of)
  • The advanced design processes and methodologies and the ability to adapt them in open ended situations.

Intellectual / cognitive skills

  • Analyse and solve problems
  • Think strategically
  • Synthesis of complex sets of information
  • Understand the changing nature of knowledge and practice in the management of culturally diverse construction environments
  • Select and transfer knowledge and methods from other sectors to construction-based organisation
  • Produce sound designs to meet specified requirements such as Eurocodes, deploying commercial software packages as appropriate
  • Dynthesis and critical appraisal of the thoughts of others

Professional practical skills

  • Awareness of professional and ethical conduct
  • Extract data pertinent to an unfamiliar problem, and apply its solution using computer based engineering tools where appropriate
  • Evaluate and integrate information and processes in project work
  • Present information orally to others
  • Show a capability to act decisively in a coordinated way using theory, better practice and harness this to experience
  • Use concepts and theories to make engineering judgments in the absence of complete data
  • Observe, record and interpret data using appropriate statistical methods and to present results in appropriate forms for the civil engineering industry

Key / transferable skills

  • Communicate engineering design, concepts, analysis and data in a clear and effective manner 
  • Collect and analyse research data 
  • Time and resource management planning

Global opportunities

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

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



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This Master's degree is designed for students who wish to practice across a broad range environmental engineering and apply new sustainable risk management strategies for complex environmental problems. Read more
This Master's degree is designed for students who wish to practice across a broad range environmental engineering and apply new sustainable risk management strategies for complex environmental problems. Water, Waste and Environmental Engineering has been traditionally referred to as public health engineering in the United Kingdom. In this postgraduate course, the technical aspects of both natural and engineering environmental systems will be covered. There will be broad interdisciplinary subjects synthesizing knowledge from a wide spectrum of science and engineering, expanding the content of public health engineering, which in the UK has traditionally been responsible for developing the infrastructure for managing water and waste.

Students will develop engineering skills and be able to design, develop and apply concepts for water and waste as a resource based on environmental sensitivity and be competent in planning, modelling, design, construction, operations, maintenance and control of both engineered and natural water and earth resources.

Students who select this postgraduate programme will gain a skill set that will enable them to progress in the fields of:

- Environmental engineering
- Desalination and water reuse
- Water resources engineering
- Hydraulics and hydrology
- Environmental fluid hydraulics
- Environmental remediation
- Waste management
- Other specialities valued in both the private and public sectors.

The MSc in Water, Waste and Environmental Engineering will incorporate solid waste management, contaminated land treatment and the use of geographic information systems (GIS) with emphasis on management of the earth's resources.

The programme will explain the relationship between different earth resources including hydrosystems, both 'engineered' - hydro-power plants, water/wastewater treatment plants, sewers - and 'natural' - rivers, lakes, wetlands, irrigation districts, reservoirs etc., solid wastes, brownfield land, and geo-derived primary resources and their sustainable management.

The aims of the programme are:

- To show you how to design, implement and manage sustainable, risk-reduced eco-friendly solutions for reducing the environmental impact of exploitation of earth's resources in the context of environmental engineering-related issues facing global societies

- To provide you with the skills to further your careers in these areas

- To support you in understanding the innovative and pioneering approaches in this field and to be able to apply them to the solution of real-world problems in developing novel industrially-relevant solutions.

Visit the website http://www2.gre.ac.uk/study/courses/pg/enggen/wwee

What you'll study

Full time
- Year 1:
Students are required to study the following compulsory courses.

Environmental Engineering and Sustainability (15 credits)
Hydrosystems Engineering and Management (15 credits)
Individual Research Project for Civil and Environmental Engineering (60 credits)
Information Technologies for Environmental Engineering (15 credits)
Research, Planning and Communication (15 credits)
Waste Management and Remediation Technology (15 credits)
Desalination and Water Reuse (15 credits)
Water and Sanitation for Developing Countries (15 credits)
Water and Wastewater Engineering (15 credits)

Part time
- Year 1:
Students are required to study the following compulsory courses.

Environmental Engineering and Sustainability (15 credits)
Information Technologies for Environmental Engineering (15 credits)
Waste Management and Remediation Technology (15 credits)
Desalination and Water Reuse (15 credits)

-Year 2:
Students are required to study the following compulsory courses.

Hydrosystems Engineering and Management (15 credits)
Individual Research Project for Civil and Environmental Engineering (60 credits)
Research, Planning and Communication (15 credits)
Water and Sanitation for Developing Countries (15 credits)
Water and Wastewater Engineering (15 credits)

Fees and finance

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

Teaching and learning

The number of contact hours (e.g. lectures, seminars and feedback on assignments) per module/course ranges from 50-75 hours for the one year full time programme or roughly equivalent to four hours per week per module. The expected self-study time is approximately 80-90 hours per module per year (roughly equivalent to four hours per week per module).

You will be taught by academics with a range of industrial and academia experience for each module.

Assessment

Project work, assignments and laboratory exercises in addition to substantial written examination of course materials will occur in most modules. The Environmental Engineering Research Project will require submission of a substantial final report/dissertation. Assessment of this module will involve participation in a poster and seminar presentation and a final oral examination.

Professional recognition

Accreditation will be sought from the Chartered Institution of Water and Environmental Management (CIWEM) and The Joint Board of Moderators (JBM) including the Institution of Civil Engineers, The Institution of Structural Engineers, the Chartered Institution of Highways and Transportation and Institute of Highway Engineers.

Career options

Postgraduate students from this programme will find such employment opportunities as engineers, scientist and technical managers in the private sector (engineering design firms, engineering consultancy, project management, risk management and waste management), in the public sector (environmental protection engineering, regulations and standards, local government) and in non-governmental sectors (NGOs, environmental advocacy) or may wish to pursue further qualifications such as a PhD within the Faculty of Engineering and Science at the University of Greenwich to become even more specialised. Employers of environmental engineers include engineering consultancies (such as AECOM, Atkins, Mott MacDonald Group, Hyder), government agencies (such as Environment Agency, Scottish Environment Protection Agency) and NGOs (such as Oxfam, Engineers without Boarders, Water Aid).

Careers and employability

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

Students also benefit from the services provided by the university’s Guidance and Employability Team, including ‘JobShop’, mentoring, volunteering and the student ambassador scheme.

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

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The Master of Engineering Studies in Geotechnical Engineering programme aims to further educate graduate students in the discipline of geotechnical engineering so as to enhance their contribution to engineering practice. Read more

Invest in your future

The Master of Engineering Studies in Geotechnical Engineering programme aims to further educate graduate students in the discipline of geotechnical engineering so as to enhance their contribution to engineering practice.

Graduates will be able to take leading roles in planning, evaluating, designing, constructing, maintaining, and managing the geotechnical infrastructure.

The programme alsos provide valuable background expertise for those wishing to enter into asset management or to begin to pursue a career in research and development.

The Master of Engineering Studies in Geotechnical Engineering programme aims to build on the geotechnical content of the BE (Civil) degree and develop graduates with enhanced ability to contribute to geotechnical engineering practice.

New Zealand is a stimulating country in which to practise geotechnical engineering with its young and varied geology, seismic activity and diverse rainfall patterns. Many unique problems occur here as a result and these present challenges for innovative and novel solutions.

The programme has been designed with courses relevant to the New Zealand geotechnical environment, to fill the needs of the country.

There is a large demand for geotechnical engineers in the local workplace, as well as a worldwide shortage of geotechnical professionals.

Programme Structure

Taught (120 points)
The Geotechnical Engineering specialisation is offered as a taught masters (eight courses).

Electives

Elective enrolments may depend on your prior study and professional experience, but ultimately, choosing the appropriate courses and topics can allow you to concentrate on and develop strengths in your energy field of choice.

Our broad list of electives include courses in:
• Design of Earthquake Resistant Foundations
• Earthquake Engineering
• Rock Mechanics and Excavation Engineering
• Soil Behaviour
• Geotechnical Earthquake Engineering
• Engineering Geological Mapping
• Geological Hazards
• Advanced Engineering Geology
• Hydrogeology
• Studies in Civil Engineering
• Foundation Engineering
• Slope Engineering
• Engineering Geology
• Ground Improvements and Geosynthetics Engineering
• Geotechnical Modelling
• Advanced Mathematical Modelling
• Surface Water Quality Modelling
• Risk, LCA and Sustainability

Next generation research at the Faculty of Engineering

The Faculty of Engineering is dedicated to providing you with all the facilities, flexibility and support needed for you to develop the skills needed for the workforce. We boast research themes and programmes that provoke interdisciplinary projects, bringing together expertise from our five departments, other faculties, and industry partners and research organisations. Collaborative study is strongly encouraged – postgraduates in particular have the benefit of experiencing cohorts with diverse academic and industry backgrounds.

You will gain access to world-renowned experts who actively demonstrate the positive impacts research have on society. High-performance equipment and labs beyond industry standards are at your fingertips. Our facilities extend beyond study hours – we take pride in our involvement in student events and associations across the University, and are dedicated to providing you with academic, personal and career advice. We encourage you to take advantage of our resources, and use them to expand the possibilities of your research and career path.

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Our mission is to educate engineers who can design infrastructures and plan human development while balancing environmental health and the society’s need for better living conditions. Read more

Mission and goals

Our mission is to educate engineers who can design infrastructures and plan human development while balancing environmental health and the society’s need for better living conditions. The MSc in Environmental and Land Planning Engineering focuses on a broad range of interdisciplinary professional capabilities and expertise required to deal with all the issues related to a sustainable utilization of natural resources. We provide a full track in English, which offers a panoply of specialized courses and laboratories addressing all the environmental components, air, water, soil and the biota, and the impacts due to natural hazards and to human activities, as well as their mitigation. We achieve the mission through advanced scientific and technological education.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/environmental-and-land-planning-engineering/environmental-engineering-for-sustainability-track/

Career opportunities

Graduates are expected to be employed in land and environmental service enterprises, engineering firms for design and construction of plants for water and air emissions treatment, energy generation and waste disposal, companies for producing and managing environmental instrumentation, remote sensors and environmental monitoring systems and networks, public authorities and agencies for land planning and control.

The track in Environmental engineering for sustainability is taught in English.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Environmental_Engineering_for_Sustainability.pdf
Our mission is to educate engineers who can design infrastructures and plan human development while balancing environmental health and the society’s need for better living conditions. The MSc in Environmental and Land Planning Engineering focuses on a broad range of interdisciplinary professional capabilities and expertise required to deal with all the issues related to a sustainable utilization of natural resources. We provide a full track in English, which offers a panoply of specialized courses and laboratories addressing all the environmental components (air, water, soil and the biota) and the impacts due either to natural hazards or to human activities, as well as their mitigation. We achieve the mission through advanced scientific and technological education.
Graduates are expected to be employed in land and environmental service enterprises, engineering firms for design and construction of plants for water and air emissions treatment, energy generation and waste disposal, companies for producing and managing environmental instrumentation, remote sensors and environmental monitoring systems and networks, public authorities and agencies for land planning and control.
The track in Environmental engineering for sustainability is taught in English.

Subjects

Available courses include: chemistry for sustainability, soil remediation, engineering and process technologies for water, air and solid wastes treatment, hydrology and hydraulic engineering, ecology, energy systems technologies, environmental impact assessment and quality evaluation, environmental systems engineering and management, geotechnical and seismic engineering, water, land and soil resource management, surface and subsurface water quality modelling and evaluation.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/environmental-and-land-planning-engineering/environmental-engineering-for-sustainability-track/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/environmental-and-land-planning-engineering/environmental-engineering-for-sustainability-track/

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

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Graduate students will find the programme of substantial use in developing their knowledge and skills base for bridge analysis, design and management. Read more

Graduate students will find the programme of substantial use in developing their knowledge and skills base for bridge analysis, design and management.

The programme also offers the opportunity for practising bridge engineers to update their knowledge of current design and assessment codes and guidelines, become familiar with developments in new techniques for the design, construction and management of bridges.

The Bridge Engineering programme encompasses a wide range of modules addressing the whole life-analysis of bridge structures from design to end-of-life.

Optional modules from some of our other study streams are also offered, covering structural engineering, geotechnical engineering, water engineering, construction management, and infrastructure engineering and management.

Graduates are highly employable and may progress to relevant specialist PhD or EngD research programmes in the field.

Programme structure

This programme is studied over either one year (full-time) or between two and five years (part-time or distance learning). It consists of eight taught modules and a dissertation project.

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

Example module listing

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

Bridge Engineering Group Modules

Structural Engineering Group Modules

Geotechnical Engineering Group Modules

Construction Management Group Modules

Infrastructure Engineering and Management Group Modules

Water and Environmental Engineering Group Modules

Dissertation

Educational aims of the programme

The programme aims to provide graduates with:

  • A comprehensive understanding of engineering mechanics for bridge analysis
  • The ability to select and apply the most appropriate analysis methodology for problems in bridge engineering including advanced and new methods
  • The ability to design bridge structures in a variety of construction materials
  • A working knowledge of the key UK and European standards and codes of practice associated with the design, analysis and construction of bridge structures and the ability to interpret and apply these to both familiar and unfamiliar problems
  • The necessary technical further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer

Programme learning outcomes

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

Knowledge and understanding

  • A knowledge and understanding of the key UK and European standards and codes of practice relating to bridge engineering
  • The ability to interpret and apply the appropriate UK and European standards and codes of practiceto bridge design for both familiar and unfamiliar situations
  • A knowledge and understanding of the construction of different types of bridge structures using different types of materials (e.g. concrete and steel)
  • A knowledge and understanding of the common and less common materials used in bridge engineering
  • A comprehensive understanding of the principles of engineering mechanics underpinning bridge engineering
  • The ability to critically evaluate bridge engineering concepts
  • The ability to apply the appropriate analysis methodologies to common bridge engineering problems as well as unfamiliar problems
  • The ability to understand the limitations of bridge analysis methods
  • A knowledge and understanding to work with information that may be uncertain or incomplete
  • A Knowledge and understanding of sustainable development related to bridges
  • The awareness of the commercial, social and environmental impacts associated with bridges
  • An awareness and ability to make general evaluations of risk associated with the design and construction of bridge structures including health and safety, environmental and commercial risk
  • A critical awareness of new developments in the field of bridge engineering

Intellectual / cognitive skills

  • The ability to tackle problems familiar or otherwise which have uncertain or incomplete data (A,B)
  • The ability to generate innovative bridge designs (B)
  • The ability to use theory or experimental research to improve design and/or analysis
  • The ability to apply fundamental knowledge to investigate new and emerging technologies
  • Synthesis and critical appraisal of the thoughts of others;

Professional practical skills

  • The awareness of professional and ethical conduct
  • A Knowledge and understanding of bridge engineering in a commercial/business context
  • Ability to use computer software to assist towards bridge analysis
  • Ability to produce a high quality report
  • Ability of carry out technical oral presentations

Key / transferable skills

  • Communicate engineering design, concepts, analysis and data in a clear and effective manner
  • Collect and analyse research data
  • Time and resource management planning

Global opportunities

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

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



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What is Humanitarian Engineering?. Read more

What is Humanitarian Engineering?

‘Humanitarian Engineering’ is defined as the use of science and engineering to invent, create, design, develop, or improve technologies which promote the well-being of communities which are facing grand humanitarian challenges (fast growing populations, poor, disaster-hit, marginalised, or under-served communities).

The postgraduate course in Humanitarian Engineering is an interdisciplinary innovative educational programme for Humanitarian Engineers which promotes appropriate, sustainable, and holistic solutions to global challenges by integrating science into a broader practical scheme. This unique and cutting-edge programme will enable you to tackle global problems (energy, water, natural disasters, humanitarian logistics, conflict and wars, global health, mixed in with overpopulation, poverty and underinvestment in low-income countries) in an interdisciplinary way and equip them to address causes, consider preventative approaches, and implement suitable responses.

It is a flexible programme that provides students with an academically rigorous postgraduate level interdisciplinary training in the fields of Humanitarian Engineering, spanning from international development to humanitarianism and disaster emergencies. It involves a strong practical component with exposure to the ‘real world’ of organisations and practitioners and experience that boosts employability.

Who is it for?

The course is - by its nature - not a ‘just for Engineers’ course, instead it is for people with background in any of the following subjects: Science (e.g. Chemistry, Physics), Social Sciences (e.g. History, Politics, Sociology), Law, Health, Management, Business and Economics as well as Engineering.

The programme spans a broad range of disciplines and is ideal for students who are looking to explore all the professional and disciplinary facets of humanitarian challenges.

What will you study?

The course develops enterprising, outward-looking graduates who are both equipped to meet society’s newest and pressing challenges, and employers' demands for advanced skills and knowledge, while translating these skills into your chosen arena. Different stakeholders, beneficiaries and users (e.g. industry, policy-makers, and local communities) are involved in the programme, so that knowledge is orientated towards real world problems and challenges.

Those of you who are less tied to the bounded nature of a particular discipline are able to develop and seek learning between, beyond and across disciplines. The programme brings together an exciting group of European and International students with a diversity of academic and professional backgrounds who establish an international alumni network involved in humanitarian engineering research and practice.

At the point of application, you will choose one of three variants. Each variant offers different core and optional modules tailored to one of three pathways: general Humanitarian Engineering, Humanitarian Engineering with Sustainability, and Humanitarian Engineering with Management.

If you are having keen interest in Engineering might wish to pursue the MSc in Humanitarian Engineering with Sustainability, which focuses on renewable energy, and sustainable cities, operations, and infrastructures.

If you wish to pursue Business-related issues might prefer the MSc in Humanitarian Engineering with Management, which offers opportunities to explore project management, communication and leadership, and management of sustainable supply chains.

Course Structure

Core Modules:

  • Humanitarian Engineering: Ethics, Theory and Practices (15 credits)
  • An introduction to Global Health (15 credits)
  • Water and Environmental Management (15 credits)
  • One Humanity; Shared Responsibility (15 credits)
  • Disasters, Resilience and Urban Data (15 credits)
  • Renewable Energy (15 credits)
  • Sustainable Operations and Humanitarian Supply Management (15 credits)
  • Sustainable Cities and Infrastructures for Emergencies (15 credits)
  • Project (45 credits)

Optional Modules: 

Your choice of optional modules will help you to further tailor the programme to your interests.

  • Humanitarian Law (15 credits)
  • Design for Sustainability (15 credits)
  • Renewable Energy (core module extended from 15 credits to 30 credits)
  • Sustainable Cities and Infrastructures for Emergencies (core module extended from 15 credits to 30 credits)
  • Disasters, Resilience and Urban Data (core module extended from 15 credits to 30 credits)

 * The modules mentioned above may be subject to change. Please read our terms and conditions for more detailed information.

Teaching:

Each module will run intensively over one week and will be taught by a variety of methods: seminar, lecture, field research.

Assessment:

The core modules are assessed in a variety of ways: essay, poster, presentation, student-devised assessment.

Career Opportunities

Graduate Destinations: 

Graduates of this programme will work across a broad range of areas. Students are expected to come from a broad array of international and professional backgrounds and go on after graduation into a wide variety of professional positions. Many Humanitarian Engineering graduates will work with the governments of developing countries managing the development process (e.g. central banks, ministries of finance, rural development, and education). Others will go on to multilateral development institutions like the World Bank, the IMF, or the United Nations; others to NGO Leaders of all sizes and descriptions; and still others will go on to work in the private sector, in jobs as diverse as professional services, manufacturing, and investment banking, to name just a few. Some students may decide to pursue PhD studies.

Work Experience Opportunities: 

During the programme, students will have the opportunity to get involved in projects managed by organisations and professional services in developing and transitional countries.



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The environment has an increasingly significant impact on the way we produce materials, structures and generally, how we live. Our course aims to extend your understanding of the core disciplines of civil engineering with the added perspective of environmental factors. Read more

Why take this course?

The environment has an increasingly significant impact on the way we produce materials, structures and generally, how we live.

Our course aims to extend your understanding of the core disciplines of civil engineering with the added perspective of environmental factors. It takes into account the importance of issues such as pollution, public health and resource management which can affect the engineering process.

What will I experience?

On this course you can:

Attend lectures and seminars given by practitioners from client, contracting and consulting organisations
Gain experience of environmental assessment techniques plus a range of other skills such as mapping using GIS, GPS and remote sensing technologies
Opt to study overseas at a variety of European universities through the ERASMUS exchange scheme

What opportunities might it lead to?

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired a Accredited CEng (Partial) BEng (Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

Here are some routes our graduates have pursued:

Civil engineering
Government agencies
Environmental organisations
Consultancy
Project management

Module Details

The course is divided into three stages, the first two stages are generally taught through formal tuition, with stage three covering independent research in an academic or industrial setting.

You will build upon established fundamental civil/construction engineering and project management principles in order to confidently apply them to a range of complex construction project problems with due regard to social, economic and environmental issues.

Here are the units you will study:

Environmental Management for Civil Engineering: This unit introduces you to the main environmental issues associated with civil engineering projects and how they are considered and mitigated in the Environmental Assessment process.

Civil Engineering Science: In this unit you will study the integrated topics of analytical structural analysis, numerical analysis and solving engineering problems. Whilst being an introduction to the finite element method (FEM) and application of FEM software packages, this unit aims to give you the ability to solve engineering problems in the design of real structures.

Environmental Engineering Design Project: This unit gives you an opportunity to simulate the design activities of a civil engineering consultancy. Project briefs are typically drawn from the work of professional contacts in the civil engineering industry. You will be required to make professional contacts, obtain advice and guidance, carry out research and conduct site visits outside the University.

Strategic and General Management: In this unit you will cover management in the construction industry, and the development of organisational and project strategic direction, taking into account internal and external environments.

Independent Research Project: This covers the generic research framework within which new knowledge is discovered, and involves the practical application of research skills and techniques to a chosen system within the construction industry.

Programme Assessment

Teaching on this course will focus on small lectures, seminars and discussion groups. It will also centre on supporting your independent learning strategies, which tutorials will help to develop.

Assessment can take many forms and is geared towards the subject matter in a way that encourages a deeper understanding and allows you to develop your skills. It includes:

Examinations
Coursework
Projects
A dissertation

Student Destinations

This course is designed to equip you with knowledge and skills that employers in the construction industry expect. Alongside the technical topics, you will develop commercial and interpersonal skills required of construction industry professionals.

This course will also equip you for the real-world challenges within the specialist field of environmental engineering. You will have a specific understanding of environmental considerations within civil engineering projects enabling you to propose and implement environmentally sustainable solutions. You can expect to find roles within areas such as environmental and sustainability assessment, waste management, regulation and consultancy to name a few.

Overall, the delivery of this course and its opportunities for you to interact with the industry throughout your studies means the employment rate of our civil engineering graduates is excellent.

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The modern society relies on the work of Chemical Engineers who develop and design the processes that make the useful products for the society by efficient use and management of resources including water and energy while controlling health and safety procedures and protecting the environment. Read more
The modern society relies on the work of Chemical Engineers who develop and design the processes that make the useful products for the society by efficient use and management of resources including water and energy while controlling health and safety procedures and protecting the environment.

Chemical Engineering provides essential tools based on the concept of sustainability and low carbon footprint for changing raw materials into useful products in a safe and cost effective way. Chemical Engineers understand how to alter the chemical, biochemical or physical state of a substance, to create everything from health care products (face creams, shampoo, perfume, drugs) to food (dairy products, cereals, agro-chemicals) and water (desalination for freshwater) to energy (petroleum to nuclear fuels).

Your study at MSc level at Bradford will be a foundation for life aimed at developing a deep understanding of advanced technical principles, analytical tools, and competence in their application together with a wide range of management, personal and professional skills. The course will provide you with essential tools based on the concept of sustainability and low carbon footprint for changing raw materials into useful products in a safe and cost effective way.

Why Bradford?

Flexibility of career path – Choice of three routes:
-Chemical Engineering - advanced chemical engineering and process technology skills for exciting and challenging careers in chemical and process industries
-Petroleum Engineering -matches the needs in different areas of oil and gas production and in medium/small operating and consulting companies
-Polymer Engineering - design and operation of processes to engineer materials with advanced properties leading to careers in diverse manufacturing sectors

Research Strengths - Internationally acclaimed research activities in the following areas:
-Chemical and Petrochemical Engineering
-Polymers
-Energy
-Water
-Pharmaceutical engineering
-Coating and advanced materials engineering

Rankings

Top Five: Chemical Engineering at the University of Bradford is ranked 5th in the UK in the Guardian University League Table 2017/

[[Modules
MSc Chemical & Petroleum Engineering (Chemical Engineering Background)
-Desalination Technology
-Materials & Manufacturing Processes
-Transport Phenomena
-Design Optimisation
-Computational Fluid Dynamics
-Upstream Production & Refinery Operations
-Research Skills
-Food & Pharmaceutical Processes Engineering
-Polymer Engineering
-Risk Management
-Engineering Computational Methods
-MSc Project

MSc Chemical & Petroleum Engineering (non-Chemical Engineering Background)
-Desalination Technology
-Transport Phenomena
-Chemical Engineering Practice
-Material & Manufacturing Processes
-Design Optimisation
-Computational Fluid Dynamics
-Upstream Production & Refinery Operations
-Research Skills
-Food & Pharmaceutical Processes Engineering
-Polymer Engineering
-Risk Management
-Engineering Computational Methods
-MSc Project

Career support and prospects

The University is committed to helping students develop and enhance employability and this is an integral part of many programmes. Specialist support is available throughout the course from Career and Employability Services including help to find part-time work while studying, placements, vacation work and graduate vacancies. Students are encouraged to access this support at an early stage and to use the extensive resources on the Careers website.

Discussing options with specialist advisers helps to clarify plans through exploring options and refining skills of job-hunting. In most of our programmes there is direct input by Career Development Advisers into the curriculum or through specially arranged workshops.

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Why Surrey?. This degree mirrors the two-year Masters programme structure that is common in the USA, and is an ideal stepping stone to a PhD or a career in industry. Read more

Why Surrey?

This degree mirrors the two-year Masters programme structure that is common in the USA, and is an ideal stepping stone to a PhD or a career in industry.

The optional professional placement component gives you the opportunity to gain experience from working in industry, which cannot normally be offered by the standard technically-focused one-year Masters programme.

Programme overview

The Electronic Engineering Euromasters programme is designed for electronic engineering graduates and professionals with an interest in gaining further qualifications in advanced, cutting-edge techniques and technologies. Current pathways offered include:

  • Communications Networks and Software
  • RF and Microwave Engineering
  • Mobile Communications Systems
  • Mobile and Satellite Communications
  • Mobile Media Communications
  • Computer Vision, Robotics and Machine Learning
  • Satellite Communications Engineering
  • Electronic Engineering
  • Space Engineering
  • Nanotechnology and Renewable Energy
  • Medical Imaging

Please note that at applicant stage, it is necessary to apply for the Electronic Engineering (Euromasters). If you wish to specialise in one of the other pathways mentioned above, you can adjust your Euromaster programme accordingly on starting the course.

Programme structure

This programme is studied full-time over 24 months. It consists of eight taught modules, two modules based on experimental reflective learning and an extended project.

Please view the website for an example module listing.

Partners

The MSc Euromasters complies with the structure defined by the Bologna Agreement, and thus it is in harmony with the Masters programme formats adhered to in European universities. Consequently, it facilitates student exchanges with our partner universities in the Erasmus Exchange programme.

A number of bilateral partnerships exist with partner institutions at which students can undertake their project. Current partnerships held by the Department include the following:

  • Brno University of Technology, Czech Republic
  • University of Prague, Czech Republic
  • Universität di Bologna, Italy
  • Universität Politècnica de Catalunya, Barcelona, Spain
  • Universita' degli Studi di Napoli Federico II, Italy

Educational aims of the programme

The taught postgraduate degree programmes of the Department are intended both to assist with professional career development within the relevant industry and, for a small number of students, to serve as a precursor to academic research.

Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant). To fulfil these objectives, the programme aims to:

  • Attract well-qualified entrants, with a background in electronic engineering, physical sciences, mathematics, computing and communications, from the UK, Europe and overseas
  • Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
  • Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
  • Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
  • Provide a high level of flexibility in programme pattern and exit point
  • Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

A graduate from this MSc programme should:

  • Know, understand and be able to apply the fundamental mathematical, scientific and engineering facts and principles that underpin electronic engineering
  • Be able to analyse problems within the field of electronic engineering and find solutions
  • Be able to use relevant workshop and laboratory tools and equipment, and have experience of using relevant task-specific software packages to perform engineering tasks
  • Know, understand and be able to use the basic mathematical, scientific and engineering facts and principles associated with the topics within electronic engineering
  • Be aware of the societal and environmental context of his/her engineering activities
  • Be aware of commercial, industrial and employment-related practices and issues likely to affect his/her engineering activities
  • Be able to carry out research-and-development investigations
  • Be able to design electronic circuits and electronic/software products and systems

Enhanced capabilities of MSc (Euromasters) graduates:

  • Demonstrate transferable skills such as problem solving, analysis and critical interpretation of data, through the undertaking of the extended 90-credit project
  • Know how to take into account constraints such as environmental and sustainability limitations, health and safety and risk assessment
  • Have gained comprehensive understanding of design processes
  • Understand customer and user needs, including aesthetics, ergonomics and usability
  • Have acquired experience in producing an innovative design
  • Appreciate the need to identify and manage cost drivers
  • Have become familiar with the design process and the methodology of evaluating outcomes
  • Have acquired knowledge and understanding of management and business practices
  • Have gained the ability to evaluate risks, including commercial risks
  • Understand current engineering practice and some appreciation of likely developments
  • Have gained extensive understanding of a wide range of engineering materials/components
  • Understand appropriate codes of practice and industry standards
  • Have become aware of quality issues in the discipline

Global opportunities

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

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



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The global challenge of environmental sustainability highlights the need for holistic design and management of complex environmental and technological systems. Read more

The global challenge of environmental sustainability highlights the need for holistic design and management of complex environmental and technological systems. This interdisciplinary Master's programme presents environmental issues and technologies within a systems engineering context. Graduates will understand interactions between the natural environment, people, processes and technologies to develop sustainable solutions.

About this degree

Students will develop an understanding of systems engineering and environmental engineering. Environmental engineering is a multidisciplinary branch of engineering concerned with devising, implementing and managing solutions to protect and restore the environment within an overall framework of sustainable development. Systems engineering is the branch of engineering concerned with the development and management of large complex systems.

Students undertake modules to the value of 180 credits.

The programme consists of four core modules (60 credits), a collaborative environmental systems project (30 credits), two optional modules (30 credits) and an individual environmental systems dissertation (60 credits).

A Postgraduate Diploma (120 credits) is offered.

Core modules

  • Collaborative Environmental Systems Project
  • Environmental Systems
  • Systems Engineering and Management
  • Systems Society and Sustainability
  • Environmental Modelling

Optional modules

Options may include the following:

  • Engineering and International Development
  • Industrial Symbiosis
  • Politics of Climate Change
  • Project Management
  • Water and Wastewater Treatment
  • Urban Flooding and Drainage
  • Offshore and Coastal Engineering
  • Natural and Environmental Disasters
  • Energy Systems Modelling
  • Smart Energy Systems: Theory, Practice and Implementation
  • Indoor Air Quality in Buildings
  • Light, Lighting and Wellbeing in Buildings
  • Building Acoustics
  • Science, Technology and Engineering Advice in Practice
  • Energy Systems and Sustainability
  • Waste and Resource Efficiency

Dissertation/report

All MSc students undertake an independent research project addressing a problem of systems research, design or analysis, which culminates in a dissertation of 10,000 words.

Teaching and learning

The programme is delivered through lectures, seminars, tutorials, laboratory classes and projects. The individual and group projects in the synthesis element involve interaction with industrial partners, giving students real-life experience and contacts for the future. Assessment is through written examination, coursework, presentations, and group and individual projects.

Further information on modules and degree structure is available on the department website: Environmental Systems Engineering MSc

Careers

Career paths for environmental systems engineers are diverse, expanding and challenging, with the pressures of increasing population, desire for improved standards of living and the need to protect the environmental systems. There are local UK and international opportunities in all areas of industry: in government planning and regulation, with regional and municipal authorities, consultants and contracting engineers, research and development organisations, and in education and technology transfer. Example of recent career destinations include Ford, KPMG, EDF Energy, Brookfield Multiplex, and the Thames Tideway Tunnel Project.

Recent career destinations for this degree

  • Air Quality Engineer, National Environment Agency
  • Environmental Engineering Consultant, DOGO
  • Nuclear Analyst, EDF Energy
  • Graduate Flood Risk Engineer, Pell Frischmann
  • Project Manager, Veolia Environmental Services

Employability

The discipline of environmental systems engineering is growing rapidly with international demand for multi-skilled, solutions-focussed professionals who can take an integrated approach to complex problems.

Careers data is taken from the ‘Destinations of Leavers from Higher Education’ survey undertaken by HESA looking at the destinations of UK and EU students in the 2013–2015 graduating cohorts six months after graduation.

Why study this degree at UCL?

The discipline of environmental systems engineering is growing rapidly with an international demand for multi-skilled professionals who can take an integrated approach to solving complex environmental problems (e.g. urban water systems, technologies to minimise industrial pollution). Environmental engineers work closely with a range of other environmental professionals, and the community.

Skills may be used to:

  • design, construct and operate urban water systems
  • develop and implement cleaner production technologies to minimise industrial pollution
  • recycle waste materials into new products and generate energy
  • evaluate and minimise the environmental impact of engineering projects
  • develop and implement sound environmental management strategies and procedures.

UCL Civil, Environmental & Geomatic Engineering is an energetic and exciting environment in which to explore environmental systems engineering. Students have the advantages of studying in a multi-faculty institution with a long tradition of excellence in teaching and research, situated at the heart of one of the world's greatest cities.

Accreditation

The progamme is accredited by the Joint Boad of Moderators, which is made up of the Institution of Civil Engineers, The Institution of Structural Engineers, the Chartered Institutions of Highways and Transportation, and the Institute of Highway Engineers.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

The following REF score was awarded to the department: Civil, Environmental & Geomatic Engineering

60% rated 4* (‘world-leading’) or 3* (‘internationally excellent’)

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.



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See the Department website - http://www.rit.edu/kgcoe/program/sustainable-engineering-0. Sustainable engineering refers to the integration of social, environmental, and economic considerations into product, process, and energy system design methods. Read more
See the Department website - http://www.rit.edu/kgcoe/program/sustainable-engineering-0

Sustainable engineering refers to the integration of social, environmental, and economic considerations into product, process, and energy system design methods. Additionally, sustainable engineering encourages the consideration of the complete product and process lifecycle during the design effort. The intent is to minimize environmental impacts across the entire lifecycle while simultaneously maximizing the benefits to social and economic stakeholders. The master of engineering in sustainable engineering is multidisciplinary and managed by the industrial and systems engineering department.

The program builds on RIT’s work in sustainability research and education and offers students the flexibility to develop tracks in areas such as renewable energy systems, systems modeling and analysis, product design, and engineering policy and management. The program is offered on campus, and available on a full- or part-time basis.

Educational objectives

The program is designed to accomplish the following educational objectives:

- Heightened awareness of issues in areas of sustainability (e.g., global warming, ozone layer depletion, deforestation, pollution, ethical issues, fair trade, gender equity, etc.).

- Clear understanding of the role and impacts of various aspects of engineering (design, technology, etc.) and engineering decisions on environmental, societal, and economic problems. Particular emphasis is placed on the potential trade-offs between environmental, social, and economic objectives.

- Strong ability to apply engineering and decision-making tools and methodologies to sustainability-related problems.

- Demonstrated capacity to distinguish professional and ethical responsibilities associated with the practice of engineering.

Plan of study

Technical in nature, the program equips engineers with the tools they need to meet the challenges associated with delivering goods, energy, and services through sustainable means. In addition to basic course work in engineering and classes in public policy and environmental management, students are required to complete a capstone project directly related to sustainable design challenges impacting society. Many of these projects can be incorporated into sustainability themed research by RIT faculty in the areas of fuel-cell development, life-cycle engineering, and sustainable process implementation.

Students must successfully complete a total of 36 credit hours through course work and a capstone project. This program is designed to be completed in three semesters.

Curriculum

- First Year

Fundamentals of Sustainable Engineering
Engineering of Systems I
Renewable Energy Systems
Lifecycle Assessment
Engineering Elective

- Second Year

Engineering Elective
Social Context Elective
Technology Elective
Engineering Capstone

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Summary. This course is unique in Ireland for its breadth across a range of infrastructure disciplines such as water, waste, structures, highways, road safety, project management and sustainability, with strong emphases on design. Read more

Summary

This course is unique in Ireland for its breadth across a range of infrastructure disciplines such as water, waste, structures, highways, road safety, project management and sustainability, with strong emphases on design. The knowledge and understanding covers key areas of civil and infrastructure engineering and meets the needs of graduates seeking chartered status. It has significant input from the expertise of a blend of current practitioners and research-led academics, with inter-disciplinary teaching in design and sustainability modules; all of this is integrated and delivered within the principles and practice of sustainable development.

About

This technical masters programme focuses on Technical subjects in a framework of Design and Sustainability, and this approach is grounded in technical modules covering waste, water, structural design, utilities, road safety and highways, supported by project management and sustainable development; a large Dissertation brings research-led studies and unique knowledge with substantial industrial linkages. Sustainable Development is the key driver in the design, delivery and assessment of all curricula and material; also, all content is set in the context of scholarly activity in which academic research is blended with professional knowledge and experience to provide a rich learning environment. Input from leading professionals as guest lecturers, mentors and advisors enhances the delivery and educational experience. Therefore the course offers a linked postgraduate course which is intellectually coherent, academically challenging, progressive in nature (with appropriate exit points) and has vocational relevance to the disciplines of civil and infrastructure engineering, as well as being linked to transport, construction, waste management and water engineering. It is designed to provide: (1) development of infrastructure engineering in the context of global sustainability and local strategic drivers, by studying relevant theoretical concepts and making critical reflection on their application;& (2) access to multi and interdisciplinary teaching and professional strengths of the Faculty staff;& (3) innovation in teaching, learning and assessment strategies, thereby relating to current professional practice; (4) leaders of infrastructure engineering for the future; and;(5) opportunities for graduates and professionals within the broad construction and built environment industry to enhance their knowledge and skills through the application of appropriate methods and techniques.

Attendance

Attendance is full-time for one year over 3 Semesters, commencing normally in September, but it is also possible to commence in January.

Attendance for the part-time Postgraduate Diploma is over 3 years, requiring attendance in 2 semesters of Years 1 and 2, and attendance in Year 3 as agreed with the Dissertation supervisor

Semester 1 - Compulsory: Project Management Practice; Integrated Design Studies; Optional – two from: Utilities and Water Engineering, Road Safety Engineering or Highway Asset Management; total of 4 x 15 credit modules.

Semester 2 - Compulsory: Sustainable Development; Infrastructure Design Studies; Optional – two from Structural Design for Infrastructure, Waste Systems or Road Safety Engineering; total of 4 x 15 credit modules.

Semester 3 – Compulsory: Dissertation - 1 x 60 credit module. Study will normally involve a weekly 12 hours of lectures, tutorials, site visits, design studio work, with independent study of 20+ hours.

Professional recognition

Institute of Highway Engineers (IHE) 

Accredited by the Institute of Highway Engineers (IHE) on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

Institution of Structural Engineers (IStructE) 

Accredited by the Institution of Structural Engineers (IStructE) on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

Chartered Institute of Highways and Transportation (CIHT) 

Accredited by the Chartered Institution of Highways and Transportation (CIHT) on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

Institution of Civil Engineers (ICE) 

Accredited by the Institution of Civil Engineers (ICE) on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

Career options

Graduate employment may be found in public or private sectors in built environment disciplines, especially in the careers of civil engineering, transportation, public health or environmental engineering, dealing with many key activities such as utilities, construction, design, infrastructure, sustainability, environmental and traffic impacts and waste management. Skills developed will include rational thinking, integrative studies and recent knowledge of current issues such as legislative structures, sustainability challenges, design practices, research-led knowledge. Recent graduates have found professional employment in the UK Water Sector, Australian engineering industries, Scottish Local Authorities, Irish County Councils, major consulting engineers and in Research posts.



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