Programme of Study for MSc Urban Water Engineering and Management
The course starts with fundamental processes and concepts associated with hydrology and the water cycle, hydraulics, environmental chemistry, environmental microbiology and environmental sampling and data analysis. Once these fundamental skills and knowledge are in place, students complete modules in more applied subjects such as design and performance of urban drainage, storm water management, modelling water distribution networks and environmental river processes. In parallel to these, the course develops specific management and assessment techniques in asset management and whole life costing, and risk analysis and extreme events. All modules include the latest research-driven science, engineering and management. The table below gives you an idea of the broad content covered by each module available in this course. Click on the module title to access the detailed module programme, which provides information on specific topics taught and the study time involved.
One third of the MSc is dedicated to an individual dissertation topic, allowing original research and independent study into a subject selected by the student from a wide range of science, technology and industry-driven options. The dissertation allows the students to develop their personal interests and significantly enhance their skills and abilities, in particular in problem solving, critical analysis and evaluation and time and resource management.
|
Module
|
Delivered
|
What is Covered
|
|---|---|---|
| Semester 1 | ||
|
Weeks 1-15
|
Microbial metabolic activity shapes the chemical characteristics of natural environments through biogeochemical nutrient cycles and mediates the transformation of pollutants that are released to the environment through the biodegradation processes. An understanding of these processes and their rates and limitations studied from a microbiological perspective provides underpinning science for predicting the transformation of pollutants and applying the associated risk assessment and environmental restoration methods. | |
|
Weeks 1-6
|
This module provides an introduction to global water resource issues and quantitative skills for generating design rainfalls and predicting runoff. It explains key processes within the hydrological cycle, how to generate specific (UK) rainfall events for engineering design purposes, and modelling approaches to predict catchment runoff response to rainfall inputs. Broader issues relating to climate change, water scarcity, flooding, water quality and hydrological measurement are also covered. Guest lecturers provide information on current developments and an industrial perspective. | |
|
Weeks 1-6
|
This module covers the principles of water flow in pipes, open channels and aquifers, and provides students with the quantitative techniques to analyse and predict such flows. The course is designed to bring students from a wide range of scientific or engineering backgrounds to a common level of understanding in preparation for the more advanced and specialised modules to follow in their postgraduate studies. The course will cover basic principles (hydrostatics, energy and momentum), and then move to the principles and techniques used in different areas (pipelines, open channels and aquifers). | |
|
Weeks 7-9
|
This course is based on the use of fundamental theoretical approaches from the fields of chemical thermodynamics and chemical kinetics to provide a rigorous tool to understand, describe and quantitatively predict the fate of contaminants in the environment. Understanding the extent and rate of the chemical transformation of pollutants in natural environments lies at the heart of risk-based environmental management. Applications of the fundamental theory are given through case studies and examples from recent published literature. | |
|
Weeks 10-12
|
This module provides students with an understanding of sampling techniques and analysis of collected data for environmental applications. The module covers environmental sampling from planning and design to selection of sampling techniques, using statistics as a tool to improve data quality and accuracy. The use of common statistical methods for data analysis and interpretation as well as an introduction to the use of multivariate statistics is also included. The theoretical concepts are illustrated using examples from surface water, groundwater and soil studies. | |
|
Weeks 13-15
|
Knowledge, understanding and ability will be gained for the application of commercial computational software to solve the complex problems associated with managing and operating water distribution networks, including the latest research ideas relating to leakage, online systems and water quality. Distribution modelling skills are highly sought after through out the international water supply sector. | |
| Semester 2 | ||
|
Weeks 1-15
|
All MSc students complete an independent dissertation project. This module aims at developing the skills necessary to complete a dissertation, including time and project management, research techniques, and academic writing. Students gain experience in public speaking by making a presentation on their dissertation at an MSc conference at the end of their programme. | |
|
Weeks 1-3
|
Urban drainage systems are essential infrastructure that helps reduce the risk of flooding and pollution of receiving waters. To design such systems, understanding is required of the concepts, design inputs and processes associated with both the quantity and quality of rainfall runoff, overland flow and in-sewer processes. This course emphasizes these concepts and illustrates their use in a case study. Recent advances in best management practices and integrated modelling scenarios will also be examined. | |
|
Weeks 4-6
|
This module will provide students with knowledge of flood risk management. The module will describe the technical, social and political issues surrounding flood risk management. The course will discuss risk due to pluvial and fluvial flooding and what measures can be taken to reduce risk. Real life examples will be used to introduce modelling software in order to evaluate flood risk. Methods of flood alleviation/control techniques will also be described and relative advantages discussed. | |
|
Weeks 7-9
|
This module introduces formal risk analysis, a probabilistic technique used by engineers to evaluate the chance of a structure failing or a natural hazard affecting an engineering structure or causing a fatality. Engineering design is often undertaken in the context of an acceptable risk, such as the design of flood defences for a one hundred year flood. Risk issues and risk analysis, including physical modelling, is covered in this context. Students are introduced to statistical tools for risk analysis, distribution theory, extreme value theory and survival analysis. | |
|
Weeks 10-12
|
The hydraulics of open channel flows and the physical processes and mechanisms involved with soluble and sediment pollutants will be covered in this course. An understanding of how the techniques and knowledge gained can help water engineers and environmental managers to better manage rivers is developed. | |
|
Weeks 13-15
|
To promote the efficient and sustainable use of resources in the developed world there is a recognised need to make best use of existing infrastructure. Whole life costing methodologies satisfy this need by considering all the costs (private & social) over a useful lifetime. This module is run in association with SEAMS Ltd. and involves training and practical application of the leading industry software. | |
† Generally 1 day per week scheduled around block modules