This flexible MSc programme is suitable for individuals who already have an accredited undergraduate civil engineering degree and who are seeking to further their engineering skills and achieve chartered status.
The course is accredited by the Joint Board of Moderators as meeting the requirements for further learning for a chartered engineer (CEng) for candidates who already have an accredited CEng (partial) BEng(Hons) or an accredited IEng (full) BEng/BSc(Hons) undergraduate first degree.
You will study a range of advanced civil engineering subjects linked to cutting-edge research. These include earthquake engineering dynamics and design, advanced geotechnics and rock mechanics, bridge engineering and advanced hydraulics. You will also develop the skills demanded in civil engineering consultancy offices around the world.
On the course, you will have the opportunity to use state-of-the-art laboratories and advanced technical software for numerical modelling.
The course is flexible and allows you to combine advanced civil engineering with related subjects including water environmental management, construction management and sustainable construction.
All of the taught modules are delivered by research-active staff and pave the way for a career at the forefront of ambitious civil engineering projects.
Scholarships are available for this course. Please click the link below for more information. https://www.brighton.ac.uk/studying-here/fees-and-finance/postgraduate/index.aspx
Our courses are under continual review. If you have already applied you can find more information on the applicant portal.
The course has an emphasis on practical applications of advanced civil engineering concepts. You will make use of our advanced laboratories, modern computer facilities and technical software.
The MSc requires successful completion of six modules together with a dissertation on an agreed technical subject; a dissertation is not required, however, for the PGDip.
The taught component of the course comprises six core modules, and you can either take all six of these modules or choose four with an additional two approved modules from other MSc courses in the School of Environment and Technology. You can use this flexibility to study related subjects including water and waste-water treatment technology, construction management and sustainable construction.
Core modules cover geotechnical earthquake engineering, dynamics of structures with earthquake engineering applications, seismic design of reinforced concrete members, random vibrations of structures, bridge loads and analysis, rock mechanics, hydrogeology, coastal engineering and wave loading.
Areas of study
• Coastal Engineering and Wave Loading
This module provides a basic understanding of different wave theories and their applications in coastal engineering practice.
You will develop an understanding of the coastal sediment transport processes and the means to deal with issues associated with coastal protection and sea defence.
• Geotechnical Earthquake Engineering
This module provides an understanding of advanced geotechnical design methods with an emphasis on seismic design. It focuses on current design methods for soil and rock structures and foundation systems subject to complex loading conditions.
You will gain experience in using a variety of commercial software.
• Rock Mechanics
The module gives you an understanding of the behaviour of rocks and rock mass and enables you to evaluate the instability of rock slopes and tunnels in order to design reinforcements for unstable rock.
• Dynamics of Structures with Earthquake Engineering Applications
You will be introduced to the fundamental concepts of dynamics of structures. The module then focuses on analytical and numerical methods used to model the response of civil engineering structures subjected to dynamic actions, including harmonic loading, blast and impact loading, and earthquake ground motion.
• Random Vibration of Structures
The module gives you the confidence to model uncertainties involved in the design of structural systems alongside a framework to critically appraise probabilistic-based Eurocode approaches to design.
Stochastic models of earthquake ground motion, wind and wave loading are explored. Probabilistic analysis and design of structures is undertaken through pertinent random vibration theory.
You will become confident with the probabilistic analysis for the design against earthquake, wind and wave loadings through various checkable calculations.
• Repair and Strengthening of Existing Reinforced Concrete Structures
The module gives you an understanding of the types and causes of damage to reinforced concrete structures. It then focuses on current techniques for repair and strengthening of existing structures.
The course is particularly appropriate for work in structural, geotechnical and coastal engineering.
Graduates have gone on into roles as structural engineers and civil engineers in a number of structural design offices around the world.
Others have been motivated by the research component of the course and followed a PhD programme after graduation.