Department of Civil and Structural Engineering,
Faculty of Engineering
This course offers a broad-based knowledge in civil engineering covering geotechnical, structural and water engineering, placing an equal emphasis on both analysis and design. You will dissect these three areas and their inherent interconnections, giving you the skills to become an effective civil engineer.
The core modules give you a grounding in engineering analysis and design. In the second semester, you can follow your interests and choose from a list of specialist modules.
Our department is research-led, meaning you’ll be taught about the latest ideas and concepts within the field, while the advanced research project provides you with an opportunity to explore a current issue in civil engineering in much greater detail.
You will be equipped to work on strategies to remedy problems such as making our construction practices more sustainable and efficient, ensuring a safe and clean water supply for future generations, or tackling coastal flooding and groundwater pollution.
This degree 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. See the Joint Board of Moderators website for more details.
- Research and Professional Skills
This module fosters best practice in engineering-related research/professional skills and delivers a range of training activities to meet the needs of professional engineers dealing with research and technological development.15 credits
- Structural Analysis
This module is designed to give you fundamental knowledge and skills related to the analysis and design of concrete and steel structural elements. Significant emphasis in this module is on the fundamental understanding of how structural members work and of the analysis behind the design codes. This helps the engineer develop a feel for the behaviour of beam and column elements that is often missing when design is based solely by using codes of practice or by the direct application of prescribed equations. This understanding will become more vital for efficient and sustainable structures into the future.15 credits
- Advanced Geotechnics
The module will provide you with greater understanding of geotechnical design in practice, advancing formative geotechnical engineering courses but critically, extending to the interpretation, analysis and forensic review of failed geotechnical systems and the governing soil-structure interaction relations.15 credits
Aspects of uncertainty and risk will be developed pertaining to ultimate and serviceability limit states, understanding soil constitutive behaviour and advanced modelling approaches (physical and numerical). Investigative forensic analysis will be conducted by you, in the context of a design project, benefiting from site investigation, physical modelling (centrifuge) observations, verified by numerical analysis that integrate suitable soil constitutive behaviour.
- Geotechnical Design
This module is designed to develop (a) your understanding of the use of limit analysis in geotechnical engineering and (b) the concepts behind geotechnical limit state design and how safety and idealisations are built into design calculations to deal with the complexity of groundwater, soil behaviour and modelling issues. Through lectures, tutorial sheets, and software exercises, you will develop your knowledge of design calculations for retaining structures and foundations in the context of Eurocode 7. You will also develop your ability to use a range of state of the art engineering design concepts and tools.15 credits
- Advanced Engineering Research Study
This module represents a major element of the Masters programme, with the aim of enabling you to learn skills in scientific investigation and in running and presenting a project. You are required to submit a comprehensive (bound) report describing the individual work that you have done during the summer semester.60 credits
- Engineering Hydraulics
This module aims to provide a solid base for the analysis of water flows in closed and open ducts. The module provides basic physical insights of the dynamics of laminar and turbulent flows in pipes and open channels. It will also give you a detailed overview of the governing equations and assumptions involved in their application at different scales of analysis. You will gain understanding and competence in the analysis of flows in different contexts and the practical application of these to solve common water engineering problems.15 credits
- Engineering Hydrology and Hydrogeology
This module is intended to provide an introduction to Hydrology and Hydrogeology for MSc Water Engineering and MSc Civil Engineering students, to equip you with basic quantitative skills for conducting mass balance calculations as well as hydrological and hydrogeological investigations. The module content comprises the prediction of rainfalls, quantitative and qualitative analysis of water movement over the surface and through the subsurface, the estimation of flood flows, the study of hydrologic and hydrogeological processes along with the range of space and time scales at which they occur, an overview of hydrological and hydrogeological measurement techniques, and an overview of current issues in the field, such as climate change.15 credits
- Advanced Concrete Design
This module aims to give those with a basic background in the design of reinforced concrete structures an understanding of selected advanced topics in the field, including the use of new concepts, construction techniques and materials. The module also provides a revision of some of the fundamental principles of reinforced concrete design. In particular, it deals with short and long-term deflections, creep, shrinkage, ductility, section analysis, prestressing, shear and cracking.15 credits
- Design of Earthquake Resistant Structures
The aim of this module is to teach the principles of modern seismic design of structures, the methodology of the European design code (Eurocode 8) and the main concepts of seismic performance of structures. The module will be delivered through lectures and computer-lab sessions in which you will be working on a project.15 credits
- Sustainable Drainage and Green Infrastructure
This module will introduce you to Sustainable Drainage Systems (SuDS) and Green Infrastructure. Lectures and design exercises will be used to develop your understanding of why SuDS are preferred to conventional stormwater management approaches, and to equip you with the skills to design SuDS schemes to meet relevant performance objectives. Guest lectures will raise your awareness of the inter-disciplinary aspects of SuDS, through topics focusing on, for example, urban planning, ecology and biodiversity, plant and soil processes, rainwater harvesting and evapotranspiration. The module will also include a site visit to a local SuDS scheme and discussion/interaction with an industry practitioner. Independent literature research will enable you to explore a current topic in SuDS research in detail.15 credits
- Computational Methods in Water Engineering
This core module is designed to improve your conceptual understanding of computational skills and numerical methods applied to solve practical hydraulic engineering problems. It introduces you to several mathematical and computer programming skills and involves writing your own computer codes and use openly-accessible freeware. They will be applied for computing groundwater flow with contaminant transport and free-surface flows. Through the lectures, tutorials, weekly and final assessment coursework, as well as group discussion, you will develop your knowledge in the field of computational hydraulics, including both theoretical and practical capabilities. You will also develop your ability to communicate effectively and professionally through individual report writing and interactive class participation.15 credits
- Design of Water Distribution and Sewer Networks
This module will provide you with a high level of knowledge and understanding as to how aging water distribution and urban drainage systems operate in the UK. Teaching will focus on acquiring knowledge about current regulatory and design practices. You will also be required to use industry standard software to apply hydraulic and water quality/pollution concepts to evaluate and modify the performance of water distribution and sewer networks. You will be expected to demonstrate this knowledge and understanding via application in case studies - water distribution network and a sewer network.15 credits
- Sustainable Water Resources Systems
What are the many aspects to consider for the sustainable planning, design and operation of water infrastructure? And to begin with, what is sustainability in practice? This six-block module is aimed at providing you with concepts and analytical tools to handle the complexity of delivering solutions for water sustainability. More specifically, the course covers tools to a) navigate the competing demands from the various sectors that rely on water systems, including trading-off economic, social, ecological and regulatory considerations across multiple scales; and to b) navigate the uncertain impacts of climatic, social, environmental and economic change on water supplies and demands.15 credits
The content of our courses is reviewed annually to make sure it's up-to-date and relevant. Individual modules are occasionally updated or withdrawn. This is in response to discoveries through our world-leading research; funding changes; professional accreditation requirements; student or employer feedback; outcomes of reviews; and variations in staff or student numbers. In the event of any change we'll consult and inform students in good time and take reasonable steps to minimise disruption. We are no longer offering unrestricted module choice. If your course included unrestricted modules, your department will provide a list of modules from their own and other subject areas that you can choose from.
We use a variety of teaching methods to support your learning, including tutorials, lectures, group project work, virtual learning environments and individual research. Some modules may feature input from our industrial partners, laboratory work or site visits.
Your assessments will include formal examinations, coursework and research projects. Regular feedback is also provided, so that you can understand your own development throughout the course.
1 year full-time
2:1 honours degree (BEng, MEng, BSc) in civil or structural engineering or other appropriate engineering or science subject.
We’ll consider your application if you have appropriate professional qualifications and work experience, but you’ll need a strong background in the areas covered on the course.
Overall IELTS score of 6.5 with a minimum of 6.0 in each component, or equivalent.
If you have any questions about entry requirements, please contact the department.
Fees and funding
You can apply for postgraduate study using our Postgraduate Online Application Form. It's a quick and easy process.
+44 114 222 5711
Any supervisors and research areas listed are indicative and may change before the start of the course.
Recognition of professional qualifications: from 1 January 2021, in order to have any UK professional qualifications recognised for work in an EU country across a number of regulated and other professions you need to apply to the host country for recognition. Read information from the UK government and the EU Regulated Professions Database.