There are no other courses that provide dedicated specialist training in crashworthiness and impact, resulting in many of our graduates securing employment or research offers before the course finishes. Established in 2003, this course is supported by close ties with industry, through student projects, specialist lectures and more importantly, by employing our graduates.
Designing advanced structures through novel, lightweight materials is one of the key enabling technologies for both aerospace and automotive sectors to align with national targets for reduction of carbon. In reducing inherent structural weight, it is essential not to compromise safety, as structural integrity and designing for crashworthiness become key design drivers.
Understanding how aluminium or composite structures and materials perform over their life cycles under static and dynamic loading, including crash and bird strike, requires expertise in a range of areas. As new simulation and material technologies emerge, there is a continuing need for talented employees with a strong, applied understanding in structural analysis, together with competent technical skills in numerical simulation.
Established in 2003, this course is supported by close ties with industry, through student projects, specialist lectures and more importantly, by employing our graduates.
The MSc in Advanced Lightweight Structures and Impact is directed by an Industrial Advisory Panel comprising senior engineers from aerospace sectors. This maintains course relevancy and ensures that graduates are equipped with the skills and knowledge required by leading employers.
The global challenges of climate and energy require new technologies for renewable energy sources, methods of energy storage, efficient energy use, new lightweight vehicular structures, techniques for carbon capture and storage and climate engineering. This is a broad-based MSc, designed for graduates who wish to acquire skills in energy and materials science in order to participate in the emerging challenges to meet climate change targets.
Students gain an advanced knowledge of materials science as it applies to energy and environmental technologies and research skills including information and literature retrieval, critical interpretation and analysis, and effective communication. They can benefit from modules in chemistry, physics, chemical engineering or mechanical engineering, thus offering future employers a wide-ranging skills base. Graduates will be well qualified to deal with the problems of energy decision-making and the implications for the environment.
Students undertake modules to the value of 180 credits.
The programme consists of five core modules (90 credits), two optional modules (15 credits each) and a research project (60 credits).
An exit-level only Postgraduate Diploma (120 credits) is available.
An exit-level only Postgraduate Certificate (60 credits) is available.
Students take all of the following, totalling 90 credits, and a 60-credit research dissertation.
Students take 30 credits drawn from the following:
All MSc students undertake an independent research project which culminates in a dissertation of approximately 7,000-10,000 words, an oral presentation and a viva voce examination (60 credits).
Teaching and learning
The programme is delivered through a combination of lectures, seminars, self-study and research supervision. Assessment is through unseen written examination and coursework. The literature project is assessed by written dissertation and the research project is assessed by a written report and a viva voce examination.
Further information on modules and degree structure is available on the department website: Materials for Energy and Environment MSc
The UK has committed to 80% reduction in CO2 emissions on a 1990 baseline by 2050. CERES, the organisation that represents the largest institutional investors would like to see 90% reduction by 2050. National Systems of Innovation (NSI), which includes the universities, research centres and government departments working in conjunction with industry, will need to apprehend new opportunities and change direction, diverting personnel to energy and climate issues in response to changing markets and legislation. This MSc will contribute to the supply of personnel needed for the era of sustainability.
Recent career destinations for this degree
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.
This programme is designed for graduates from a wide range of science and engineering backgrounds who wish to broaden their knowledge and skills into materials science with an emphasis on the energy and climate change issues that will drive markets over the next century. It delivers courses from five departments across three faculties depending on options and includes a self-managed research project which is intended to introduce the challenges of original scientific research in a supportive environment.
Research activities span the whole spectrum of energy-related research from the development of batteries and fuel cells to the prediction of the structure of new water-splitting catalytic materials.
Students develop experience in scientific method, techniques for reporting science and in the many generic skills required for a future career.
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: Chemistry
94% 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.
Research is central to the study of architecture within the Edinburgh School of Architecture and Landscape Architecture (ESALA). It motivates our intellectual and creative activities and underpins our collaborations with a range of important international and UK-based institutions. We actively promote interdisciplinary approaches to research in architecture.
Our expertise and interests range across the following areas:
Our focus includes conservation theory and history; urban conservation; conservation technology; and the challenges of bridging the gulf between heritage and new architecture.
We have particular strength in the history of architecture in Britain and the British colonial world (18th and 19th centuries); Germany, Central Europe and Russia; modernism in Europe, North America and Africa; Renaissance Italy; the history of landscape; the history of technology; the international history of mass housing and urban development; the theory and philosophy of architecture; the philosophy of place; and critical inquiry and methodology.
We focus on research in and through design, as informed by contemporary architectural and cultural theory; studio pedagogy; research-led teaching; and methodologies of urban research and fieldwork.
We have expertise in the spatial, social and philosophical implications of media; the relationship between computers and design practice; cognitive models of human-computer interaction; 3D modelling; mobile computing; the sonic environment; and e-commerce.
We offer expertise in lightweight steel structures; the building envelope; concrete construction; design and manufacturing; and sustainable design in both qualitative and quantitative senses, looking at environmental response, design theory, rural planning and user-centred solutions.
The MSc by Research programme comprises a compulsory research methods course, the choice of one optional course and a 20,000-word dissertation based on independent research.
The University of Bath Civil Engineering: Innovative Structural Materials MSc is a full-time, one-year taught postgraduate course.
Students study a range of modules before carrying out an individual research dissertation project in order to complete their Master of Science degree.
The course produces graduates with an in-depth and practical understanding of the use of innovative structural engineering materials in the provision of sustainable and holistic construction solutions for the built environment.
The use of construction materials is key to infrastructural development globally. New approaches are now needed for innovative renewable and low carbon structural engineering materials.
This MSc course will not only help prepare you for an exciting career in the industry, but it will also help prepare you to continue your studies onto a Doctor of Philosophy research programme.
The course is aimed at engineering and science graduates who wish to work in the construction industry.
As a student you will be provided with the practical knowledge and tools to support you in the use of innovative structural engineering materials in the context of sustainable and holistic construction. You will also learn how to harness that knowledge in a business environment. You will gain analytical and team working skills to enable you to deal with the open-ended problems typical of structural engineering practice.
The MSc is based on research expertise of the BRE Centre for Innovative Construction Materials (http://www.bath.ac.uk/ace/research/cicm/) and is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired a partial CEng accredited undergraduate first degree. Please visit the Joint Board of Moderators (http://www.jbm.org.uk/) for further information about accreditation.
The course includes traditionally taught subject-specific units and business and group-orientated modular work. These offer you the chance to gain experience in design, project management and creativity, while working with students from other subjects.
Group project work:
In semester 2 you undertake a cross-disciplinary group activity for your professional development, simulating a typical industrial work situation.
Individual project work:
In the final semester, you undertake an individual research project directly related to key current research at the University, often commissioned by industry.
A full list of units can be found on the programme catalogue (http://www.bath.ac.uk/catalogues/2015-2016/ar/ar-proglist-pg.html#AC).
Semester 1 (October-January)
The first semester provides a foundation in the most significant issues relating to the sustainable use of innovative structural engineering materials in design and construction; and involves units in natural building materials, advanced timber engineering, advanced composites, sustainable concrete technology and architectural structures.
- Five taught compulsory units
- Includes coursework involving laboratory or small project sessions.
- Typically each unit consists of 22 hours of lectures and 11 hours of tutorials, and may additionally involve a number of hours of laboratory activity and field trips with approximately 65-70 hours of private study (report writing, laboratory results processing and revision for examinations).
Semester 2 (February-May)
Semester 2 consists of a further 30 credits comprising of five core 6 credit units. These units include:
- Materials engineering in construction
- Advanced timber engineering
- Engineering project management.
Students will undertake a group-based design activity and an individual project scoping and planning unit (Project Unit 1). The group-based activity involves application of project management techniques and provides the basis for an integrated approach to Engineering, but with the possibility of specialising in the chosen master's topic.
It is a feature of this programme that the project work proceeds as far as possible in a way typical of best industrial practice. The Semester 2 project activities have significant planning elements including the definition of milestones and deliverables according to a time-scale, defined by the student in consultation with his/her academic supervisor and (where appropriate) his/her industrial advisor.
Summer/Dissertation Period (June-September)
Individual project leading to MSc dissertation.
Depending on the chosen area of interest, the individual project may involve theoretical and/or experimental activities; for both such activities students can use the department computer suites and well-equipped and newly refurbished laboratories for experimental work. The individual projects are generally carried out under the supervision of a member of academic staff.
There may be an opportunity for some projects to be carried out with the Building Research Establishment (BRE).
- Advanced structures
- Advanced composites in construction
- Advanced timber engineering
- Materials engineering in construction
- Natural building materials
- Sustainable concrete technology
The Department of Architecture and Civil Engineering brings together the related disciplines of Architecture and Civil Engineering. It has an interdisciplinary approach to research, encompassing the fields of Architectural History and Theory, Architectural and Structural Conservation, Lightweight Structures, Hydraulics and Earthquake Engineering and Dynamics.
Our Department was ranked equal first in the Research Excellence Framework 2014 for its research submission in the Architecture, Built Environment and Planning unit of assessment.
Half of our research achieved the top 4* rating, the highest percentage awarded to any submission; and an impressive 90% of our research was rated as either 4* or 3* (world leading/ internationally excellent in terms of originality, significance and rigour).
The dominant philosophy in the joint Department is to develop postgraduate programmes and engage in research where integration between the disciplines is likely to be most valuable. Research is carried out in collaboration with other departments in the University, particularly Management, Computer Science, Mechanical Engineering, and Psychology.
Find out how to apply here - http://www.bath.ac.uk/study/pg/apply/
The following postgraduate funding may be available to study the Civil Engineering: Innovative Structural Materials MSc at The University of Bath.
UK / EU: £9.500