The Earth's resources are under strain from a growing population. Now, more than ever, we need to monitor, manage and maintain our environment. This vocationally relevant Master's provides you with an in-depth critical understanding of today’s major environmental challenges.
You can keep your learning broad or you can specialise in one of four areas:
Food Security
Energy
Pollution
Ecology
There are specific core modules for each specialist area.
Several modules include field trips to the beautiful and topographically varied countryside around Lancaster, and beyond.
All options include a dissertation project, which will enhance your practical and analytical skills and give you the chance to apply your learning to a real-world challenge. Our many research projects and partners across the globe provide exciting possibilities when you are choosing your dissertation subject. Alternatively, you can do a six-month research placement with a private sector company, government body or voluntary sector organisation instead of a traditional dissertation. Examples of previous dissertations include:
Using acoustic surveys to assess rainforest mammal communities
Plant productivity and nutrient use efficiency under diffuse solar radiation
The geopolitics of deep-sea mining
Urban deprivation and flood exposure in the Brazilian Amazon
Go Wild – How much carbon could we gain by re-wilding the uplands?
More crop per drop: does “little and often” improve crop water use efficiency
This very popular course will equip you to pursue a broad range of careers including environmental monitoring, resource management and consultancy.
Dr Ian Hartley explains what to expect from an Environmental Management MSc at Lancaster, how our course is built to allow you to tailor the degree to your personal interests, and how it can be used to pave the way for a variety of environmentally-focussed careers.
Postgraduate study is carried out in the Graduate School for the Environment. This is a collaboration between Lancaster University's Environment Centre, the Centre for Ecology & Hydrology, and Rothamsted Research.
2:1 Hons degree (UK or equivalent) in Geography, Biology, Chemistry, Biological Sciences, Ecology, Social Sciences, Business, Energy or similar courses.
We may also consider non-standard applicants, especially those with extensive appropriate work experience or similar training in Environmental Management. Please contact us for information.
If you have studied outside of the UK, we would advise you to check our list of international qualifications before submitting your application.
English Language Requirements
We may ask you to provide a recognised English language qualification, dependent upon your nationality and where you have studied previously.
We normally require an IELTS (Academic) Test with an overall score of at least 6.5, and a minimum of 6.0 in each element of the test. We also consider other English language qualifications.
Delivered in partnership with INTO Lancaster University, our one-year tailored pre-master’s pathways are designed to improve your subject knowledge and English language skills to the level required by a range of Lancaster University master’s degrees. Visit the INTO Lancaster University website for more details and a list of eligible degrees you can progress onto.
Course structure
You will study a range of modules as part of your course, some examples of which are listed below.
Information contained on the website with respect to modules is correct at the time of publication, but changes may be necessary, for example as a result of student feedback, Professional Statutory and Regulatory Bodies' (PSRB) requirements, staff changes, and new research. Not all optional modules are available every year.
Core
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This module is taken by all master's students. This is a piece of research carried out with one-to-one supervision from either a member of LEC staff or one of our research partner organisations or sometimes both. Students can choose their own project (subject to agreement), choose a project from a list published by the department, or can apply for a project in conjunction with an external company.
Students will gain a critical understanding of key concepts, principles, tools and techniques for the management of natural resources and the environment. Particular attention is given to the challenges of dealing with complexity, change, uncertainty and conflict in the environment, and to the different management approaches which can be deployed in ‘turbulent’ conditions.
Contemporary environmental problems will be examined and interpreted from both an academic and policy perspective. In order to do this effectively, students will learn to evaluate and critique arguments and evidence related to environmental problems, and will demonstrate advanced understanding of alternative management concepts through constructive debate.
This module will provide an introduction to Environment Impact Assessments (EIAs), Strategic Environmental Assessments (SEAs) and their legislative context in the United Kingdom and the European Union, placed into the broader context of international policy development. It will cover aspects of Schedule 1 projects that always require an EIA, such as waste incinerators and major road schemes, and Schedule 2 projects which sometimes require an EIA, such as wastewater treatment plants, quarries and dairies.
The syllabus will include essential elements and procedures contained within EIAs including screening, scoping, assessment and evaluation of impacts and development of alternatives, reporting through an Environmental Impact Statement (EIS), review of the EIS, decision making, monitoring, compliance and auditing.
The module aims to train students to Master's level in guided, but self-determined research planning. Forthe subject area of their research project, they will have: familiarity with the broader and specific literature;researched appropriate methodologies; developed a research plan; presented the findings in poster and written formats.
Optional
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This module focuses on the fate and behaviour of contaminants in the environment, considering fundamental principles and processes which control their fate in environment systems. You will gain and understanding of the fundamental principles relating to the fate and behaviour of contaminants in environmental media for scientists with relevant degrees.
After an introduction to the importance and timeliness of civilisation - as both concept and reality - and 'ecological civilisation' in particular, the course will proceed to explore, first, multiple definitions and dimensions of civilisation and, secondly, various accounts of the dynamics of civilisation(s). The first part of the course will thus include consideration of both material and ideational aspects of civilisation, as well as it normative 'light' and 'dark' sides,and issues of the 'more-than-cognitive' that particularly speak to a concern for ‘civilisation’ (vs., say, terms relating to modern social science disciplines such as ‘society’, ‘economy’, ‘polity’). The second part of the course will explore evidence regarding the rise and fall of civilisation(s) and what may be learned regarding ‘where we are today' in trajectories of civilisation and what we could do in response.
*This module is offered in alternate years (e.g. 19/20, 21/22 etc)*
Bringing together the latest methods and applied techniques in catchment hydrology and modelling, students will gain a solid foundation in the key concepts of hydrology, hydrometrics and basic hydrological processes operating at a catchment scale.
Teaching will focus on the practical application of skills and industry standard techniques in the context of the latest legislation, guidance and policy. The module will introduce commercially available models and allow students to critically apply these models in a range of worked case studies and examples.
Students will learn to critically assess the main hydrological assessment and modelling techniques in order to effectively use hydrological data. However, they will also be expected to deal with instances where there is an absence of local data, to the extent that they will know which estimation or modelling technique to choose when faced with uncertainty in a real world situation.
This module explores climate change in the context of it being a ‘wicked problem’. The aim is to provoke students to look beyond the simple narratives pushed at us about climate change and to start to think critically as wicked problems require us to do. In doing so, students are invariably forced to abandon often naive assumptions about what can and can't be done to tackle climate related risks.
This module employs developing and using an Integrated Assessment Model (IAM) as its primary learning device because, for all their deficiencies, IAMs have become the most important way synthesising the various components of the climate change 'problem'. Practical decision making is a theme running through the module supported by quantitative analysis. However, this necessarily involves debate and discussion over the normative values we use in our analysis of climate change and students will be expected to actively participate in this debate, holding and developing their line of argument both in small groups and in class wide discussions.
By the end of this module, students will recognise the role of societal and climate dynamics in climate change management, and will gain the necessary knowledge required to comprehend the basis of sustainable development in the context of climate change management. They will also be able to perform simple, yet meaningful evaluation of a range of climate related options.
This module aims to explore and reconfigure the ways in which climate change is understood through a focus on the social, rather than the scientific-environmental discourses that have dominated the policy and politics of climate change. This module give you a wide-ranging and intensive introduction to the politics, cultures and theories of climate change research in the social sciences and humanities. You will be able to critically evaluate different theoretical perspectives on a range of climate change debates and present alternative arguments.
*This module is offered in alternate years (e.g. 18/19, 20/21 etc)*
Students will learn about the processes that lead to coastal erosion and flood risk, including tides, storm surges and waves. They will be introduced to estimation and computational techniques used to calculate extreme sea level and wave heights and for the production of tidal graphs for flood inundation modelling.
It will be delivered in the context of applying these technical approaches and concepts to decision making faced by coastal asset owners, planners, developers, etc. and will also introduce the concepts of predicting climate change impacts, the principles of adaptation, resilience and uncertainty, and how to incorporate these into flood risk management.
Students will gain an understanding of different types of numerical and physical models available for coastal flood modelling (e.g. empirical, 2D or 3D grid-based, offshore circulation, wave transformation), their strengths and weaknesses and how to deal with uncertainty.
Students will also gain skills in how to assess, quantify and mitigate the risks to coastal assets, people and the environment. In addition, this module encourages comprehension and assessment of coastal processes reports, wave overtopping studies and coastal flooding studies.
This module focuses on key challenges facing the conservation of biodiversity today. We examine trade-offs between conservation goals and human desires, and wellbeing. The module highlights emerging understanding of the complex relationships between biodiversity, ecosystem services and human life.
Students will be engaged with specific examples of how conservation science is changing to address social-economic-ecological conflicts. They are encouraged to critically analyse literature on topical issues confronting biodiversity conservation. By doing so, they will gain an understanding of the factors that constrain conservation aims, and of the need for interdisciplinary approaches to conserve biodiversity in the real world.
Those who take this module will develop an understanding of how conservation has changed, and be able to define criteria to identify species and ecosystems of high conservation importance. They will also learn how conflicts between social, economic and ecological objectives can be understood and addressed in partnerships.
This module will provide you with a broad view of issues related to contaminated land, in particular: typical contamination problems; methodologies for assessing the extent and seriousness of contamination; and the applicability and effectiveness of remediation techniques as a function of contaminant and site conditions.
The legislation pertaining to and the processes used to assess the risk associated with contaminated land will be appraised, as will risk-based approaches to contaminated land assessment in general. The fate and behaviour of contaminants in the environment will also be examined. Students will gain knowledge in these matters via the risk assessment and remediation case studies.
An awareness of the scale of contaminated land in the UK will be acquired, and students will gain the ability to scientifically discuss the processes which control the behaviour of chemicals in soil.
This module focuses on data processing and visualisation to support dissertation work, and will provide students with advanced scientific numeracy skills. It includes introductory elements of MATLAB and Simulink, the industry standard for programming language, and students will learn to design, modify, run and debug simple MATLAB programs. They will be able to adapt the skills learnt to other programming languages such as Fortran and C.
Students will be taught the main programming elements, such as data input, processing, output in numerical and graphical forms, programming tools and structures (loops, conditional statements and other flow control).The module also introduces selected principles of dynamic systems analysis such as transfer functions applied to environmental systems in the form of examples and case studies.
Coursework will include writing brief MATLAB scripts based on the scripts used during workshops, as well as an essay on selected problems of environmental systems modelling linked with these scripts. Tests will be taken which will involve writing code snippets related to simple numerical and graphical problems.
Current approaches to cutting-edge research in the environmental sciences are highly dependent on digital data, and a wide variety of different data types can now be accessed relatively easily. You only need to consider the data required to understand climate change to appreciate the diversity of information that is currently available, and which is needed to address the biggest global issues.
In this module you will learn the fundamentals of retrieving, annotating, analysing and interpreting digital data from a variety of sources, applying integrated, scientific methodologies. You will develop data manipulation skills and an awareness of the tools available to maximise the value of heterogeneous digital data. We demonstrate everyday problems in data collection, both avoidable and unavoidable, and explore techniques that minimise their impact. We discuss the strengths and weaknesses of current software for data mining and visualisation, and you will get hands-on experience of data integration using spreadsheet, database and GIS technologies.
This module provides a grounding in statistics and data analysis for non-mathematicians, by starting with the basics then developing the skills required to successfully analyse data generated through dissertation projects.
Students will familiarise themselves with the open-source statistical package 'R' for analysis. The materials covered include describing data, producing figures, comparing differences between groups, correlation and associations, regression analysis and experimental design.
The module also provides a brief overview of methods beyond the module to provide awareness and a direction for further progress.
*This is a distance learning module and not taught on Campus*
Students are provided with an insight into the physics, chemistry and engineering of common energy conversion processes, including conventional thermal power generation: coal, oil, open-cycle and combined cycle gas turbines. They will develop the ability to analyse systems efficiency and the CO2 emissions of different schemes, and will also study direct conversion, including solar photovoltaic devices and fuel cells.
This module will enable students to discuss and deduce numerically the efficiency of a variety of energy conversion processes. There will be an opportunity for students to gain a range of transferable skills such as, the ability to describe and analyse energy conversion processes. They will also gain a consideration of where current research trends are taking the field.
How have the principles of environmental law developed? How effective is the environmental law of England and Wales?
Law students and students from Lancaster Environment Centre study side by side on this module. This presents you with a rare interdisciplinary opportunity to share ideas and perspectives between lawyers and scientists. Together, we will explore the sources, principles and effectiveness of environmental law in England and Wales.
Within your studies you will investigate the efficacy and effect of environmental law. Topics analysed include: water pollution, the history of environmental law, green criminology and the protection of the countryside. The module then builds upon this critical analysis to explain how the aqueous, atmospheric and terraneous environments are protected by law.
Environmental law is typically taught by research-active academics who will introduce you to their research into green criminology, access to the countryside, market mechanisms and environmental protection. This research often informs their teaching and you can choose an essay based on these topics or develop your own question with the support of our lecturers.
The focus is to understand the component parts and the interdisciplinary basis of the global food system. To this end, students will examine challenges facing global agricultural production as a result of climate change. They will also gain an understanding of the shortage of key resources for food production and the subsequent issues that affect people’s access to food.
In addition to this, the module will demonstrate how basic plant physiology can inform both plant breeding and agronomy to increase the sustainability of agriculture. The factors impacting food safety and food quality (especially nutritive value) will also be explored.
Ultimately, students will develop a familiarity with several current/impending crises in global food security.
*This module is offered in alternate years (e.g. 19/20, 21/22 etc)*
Forecasting and Extreme Event Response will provide students with an introduction to the latest hydrological and meteorological forecasting methods and a solid foundation in the concepts and processes involved in flow forecasting. It will introduce commercially available models for real time flood forecasting and warning systems and the concepts of variability, uncertainty and accuracy in short term forecasting. It will also introduce longer term climate prediction and the concepts and principals of uncertainty.
The course will include a simulated flood response exercise to enable students to understand how forecasting is applied and how uncertainty and variability in forecasting is dealt with in a real world context. This will utilise JBA’s Exercise Management System software which simulates hydrometric data, displaying rainfall and river level information, automatic alarms, radar imagery and exercise injects to test response to realistic flooding scenarios.
This module introduces students to the fundamental principles of Geographical Information Systems (GIS) and Remote Sensing (RS) and shows how these complementary technologies may be used to capture/derive, manipulate, integrate, analyse and display different forms of spatially-referenced environmental data. The module is highly vocational with theory-based lectures complemented by hands-on practical sessions using state-of-the-art software (ArcGIS & ERDAS Imagine).
In addition to the subject-specific aims, the module provides students with a range of generic skills to synthesise geographical data, develop suitable approaches to problem-solving, undertake independent learning (including time management) and present the results of the analysis in novel graphical formats.
Taking a broad look at geological hazards, this module will cover everything from contemporary events to those that have shaped the Earth over geological time. The module explores in depth the fundamental processes involved in these events and how and to what extent such events can be predicted. Case histories of national and international disasters will be used to illustrate these hazards, and the inherent risks and potential mitigation measures will be discussed.
A demonstration and elaboration of the geological processes responsible for the occurrence, recurrence and magnitude of hazards will be given. Students will also learn to apply and report on the methods of prediction and mitigation strategies of geological hazards, and will apply simple prediction scenarios of geological hazard occurrence using geological datasets.To this end, students will develop skills in integrating sparse quantitative measurements and qualitative observations in order to derive interpretations from relevant datasets.
The module underscores far-reaching concepts such as using the past to inform the future and environmental risk. It will ultimately develop a sense of human-place in the geological world, promoting an understanding of how the geological world impacts human society, and what can be done to limit that impact.
The aim of this module is to introduce the concept of the Earth system and how the different components (atmosphere, ocean, ice and ecosystems) all interact with each other to shape the Earth's climate and control how the climate might change. The module will cover issues related to recent climate change, including natural and human drivers of the change. It will introduce the computer models and global observation networks that scientists use to understand the Earth system. It will also discuss the role of atmospheric chemistry and climate in the Earth system, including issues related to air quality, greenhouse gases and aerosols.
Overall, this module aims to provide an introduction to the physical processes which influence global climate change, leading to a better understanding of Earth system science.
Students will learn about the planning that goes into, and the ecological principles underlying, habitat management.
There will be a series of excursions to sites of conservation interest, led by external contributors and experts within the Department. Workshops will train students in habitat management techniques and planning, and students will write a conservation management plan for a particular site.
Students will be able to describe how the principles underlying the management of habitats for conservation can be applied in a range of habitat types, and will be able to construct a standard conservation management plan.
They will also develop skills in identifying, abstracting and synthesising information, and report writing.
*This module is offered in alternate years (e.g. 19/20, 21/22 etc)*
This module will deliver an introduction to flood risk management in the context of UK policies, legislation and spatial planning. It will provide a grounding in flood risk related responsibilities and will teach students the key concepts in urban hydrology and sustainable drainage systems (SuDS). To this end, the module will cover the design of SuDS systems, from outline design concepts to assessment of performance, estimation of flow and water quality loading.
Students will come to understand the capabilities and applications of the commercially available hydraulic models (e.g. Microdrainage, MUSIC) and the relative advantages/disadvantages of each, plus the data requirements. They will also learn how to plan, design, construct and manage a SuDS scheme in accordance with the relevant legal and regulatory framework.
By the end of this module, students will demonstrate the skills required to undertake a Flood Risk Assessment and will be able to select and apply the best techniques and models for estimating design flows in urban drainage systems.
Our world is facing an ever-increasing number of global environmental challenges. This engaging module examines the international legal response to those challenges.
We will delve into the socio-economic, political and scientific implications of environmental problems. As we do so, we will assess the impact of those implications on law and policy-making.
The module focuses on a number of contemporary environmental problems: climate change, marine pollution, the protection of international watercourses, fisheries and biodiversity, and the relationship between trade and the environment. You will assess the strengths and inadequacies of the law in regulating each of these issues.
We also typically cover topics such as:
fundamental concepts and principles of international environmental law
sustainable development and the precautionary principle
how international environmental law operates (law-making, environmental governance and institutional structure)
compliance with environmental rules and standards
You will be taught by academics in the field many of whom are active researchers. Typically, research within the teaching team informs this module.
Students will be given an introduction to the foundations of lake ecology, an area with an acknowledged national lack of expertise. The module presents a holistic approach to the drivers and internal interactions that control water quality in lakes.
Those who take this module will be taught basic ecological principles, which will be elucidated using lake ecology. They will also be introduced to the various applications of state-of-the-art techniques and provided with essential background information for dealing with regulation such as the Water Framework Directive.
This module also includes a field trip and practicals that will give students experience of working with the Centre for Ecology & Hydrology in a management/policy context. Modelling to predict impact of management measures is also an important aspect of the module, and an appreciation of its principles and uses when it comes to lakes and catchment will be encouraged.
Students will come to understand the state-of-the-art tools and approaches needed to study and manage lakes as used in industry, government and science.
This module is designed to give students a foundation in the numerical skills required for studying environmental science. It focuses on developing explicit links between mathematical analysis and the physical processes that govern environmental systems. Workshop sessions with members of teaching staff provide an informal atmosphere for you to refresh your mathematical knowledge, to learn how numerical skills can enrich your understanding of the environment, and to develop a scientific approach to solving a range of environmental problems. We employ environmental case studies throughout the module and analyse a number of environmental data sets.
Depending upon degree programme, students who hold an AS-level in maths do not have to take this module and as such will have a further optional module to choose from.
Following the earlier module ‘Numerical Skills I’, students will gain a more complete understanding of the numerical skills required for studying the environment. Environmental case studies will be used in a mixture of lectures and workshops where students will learn to manipulate trigonometric equations, describe the basic principles of calculus and solve simple equations. These concepts will be applied to environmental examples including radioactive decay, atmospheric pressure scale height and chemical kinetics.
Depending upon degree programme, students who hold an AS-level in maths do not have to take this module and as such will have a further optional module to choose from.
The aim of this module is to provide students with a theoretical foundation for the study of development and the environment from a geographical perspective. Students will focus on understanding the ways in which scholars have brought together development theory alongside the analysis of nature-society relations in the developing world.
This module provides students with a critical understanding of the evolution of contemporary development discourses and new ways of thinking about the relationship between environment and development. Key topics of discussion include theories of development, indigenous knowledge and development, biotechnology and food security, and the political economy of natural resources.
Ultimately, this module will enhance student’s academic skills to develop reasoned arguments through the analysis, interpretation and critical appraisal of complex evidence, with a module designed to deepen student’s understanding between theory and practice.
This module aims to provide you with knowledge of volcanoes and volcanic systems. Its foundations are an understanding of the properties and behaviour of volcanic materials gained through laboratory, theoretical and field study. The module emphasizes the widely-applicable physical and chemical processes that occur during volcanic activity, including variations in solubility, rheology, phase, density and permeability. The interaction of volcanic processes with the biosphere, atmosphere and hydrosphere are discussed. The products of volcanism, together with the hazard and benefits to life on Earth are studied.
The Renewable Energy module provides students with specialist training in this field, with strong emphasis on engineering design, but also includes discussions of costs, grid integration, optimal resource exploitation and environmental aspects. The aim of this module is to introduce students to the fundamentals of a range of sources of renewable energy and the means of its conversion into mechanical and/or electrical power. In addition, the technical, economical, environmental and ethical issues associated with the exploitation of renewable energy sources are highlighted and discussed.
Students will be provided with a good overview of well established and rapidly growing forms of renewable energy, learning fundamental design concepts of horizontal and vertical axis wind and tidal current turbines, and hydraulic turbomachinery, and analysing key power and load control strategies. An introduction to solar energy for electrical and heat power generation is also included. Student will be taught how to assess renewable energy resources, and how to reliably determine the maximum share of the available source that can be converted into electricity or heat.
Using engineering, physical and mathematical models, students will learn about the formulation and solution of multidisciplinary problems of renewable energy engineering. The discussion of realistic engineering problems and machine design/usage challenges will expose students to technologies presently used in the research and development departments of modern renewable energy organisations.
The aim of this module is to enhance the research training given to Master's students in order to improve the general quality of dissertations and research reports.
Students will be provided with basic training in research approaches, methods and techniques so they are able to describe the research traditions associated with the geography discipline, and design and undertake geographical research using appropriate methods of data collection and analysis.
In addition to this, students will undertake detailed literature reviews and formulate research questions, their answers of which will demonstrate an understanding of writing styles, structures, formats and other conventions which are common to academic research.
(This module is required for MSc Environment and Development students taking a social science rather than natural science-based dissertation)
*This module is offered in alternate years (e.g. 18/19, 20/21 etc)*
Students will be provided with a solid foundation in key hydraulic processes, the impact of structures and an overview of the generic types of river model during this module. This includes how to select the most appropriate model for a particular application for flood risk management e.g. flood warning, flood risk mapping for spatial and emergency planning, broad scale screening studies, detailed feasibility and design of flood mitigation measures.
In addition to this, commercially available 1D, 2D and integrated models will be available to use during the module. Students will critically evaluate these commercially available models and select the best model for a specific application. This involves learning to identify and quantify where uncertainty exists in data and modelling, and how it should be dealt with.
Students will benefit from the availability of a mobile hydraulic flume. It is owned by the JBA Trust for educational purposes and will be used to demonstrate hydraulic principles relating to good river weir and culvert design.
With this knowledge gained from these tools, students will be able to apply industry standard flood estimation and modelling techniques to solve real problems in the context of flood risk management and the latest legislation and policy.
Soils are fundamental to our very existence, as a vital medium for food growth and a regulator of water quality and climate. Exploring concepts within three core topics – principles of soil science, soil biology, and soil management and global change – students learn about the importance and functions of a healthy soil system.
They will develop knowledge of soil nutrient cycling, biodiversity, and water and carbon cycling processes. In addition, students will explore the issues and mitigation options related to soil compaction, erosion and water quality, and the challenges and threats faced by soils in the light of global change.
*This is a distance learning module and not taught on Campus*
*This module is offered in alternate years (e.g. 18/19, 20/21 etc)*
The module will cover the concepts and theory involved in river restoration techniques and introduce a geomorphological approach to sustainable river management. It will be based on case studies and examples of river restoration projects, delivered in the context of the developing legislative and policy drivers, such as the Water Framework Directive (WFD). It will also include a field trip to visit a local river (the River Lune) to demonstrate assessment techniques, identify sustainable solutions and provide case study material.
Students will learn how the Water Framework Directive (WFD), the ‘Catchment Based Approach’ (CaBA) and the principles of Integrated Catchment Management (ICM) influence and drive river and catchment management. They will also consider the main hydro-ecology and hydromorphology assessment techniques. This will enable students to understand the process, techniques and key steps involved in designing a sustainable river restoration scheme.
Students will be given an introduction to the origin, purpose and uses of the National Vegetation Classification (NVC) as a systematic and comprehensive survey of the plant communities of natural, semi-natural and major artificial habitats in Britain.
The module will inform students of the NVC survey’s methodology so that they can learn the basic techniques it uses. Recognising boundaries and homogeneous strands; locating sample quadrats; and recording essential features of the composition and structure of the vegetation and its relationship to the habitat, are all essential skills to acquire. They will also come to understand the potential and limitations of the NVC as a monitoring, management and design tool.
Practical field exercises will be included, and will involve data collection from a range of vegetation types with subsequent analysis, evaluation and interpretation which will provide the students with an appreciation of the complex relationships between vegetation and climate, soils and human impacts.
Students will gain knowledge of identification, sampling and monitoring methods for some key taxa and an understanding of how these methods may be used in a wider context, e.g. local, national and international contexts of different types of survey.
The module will have five sections, each delivered with one or two lectures and including a field component on campus or away. It will also include the analysis of quantitative data.
Those who take this module will be taught to identify some taxonomic groups to appropriate levels (species, genus, etc.) and will devise appropriate sampling regimes to derive population estimates or indices for population monitoring. They will also use other monitoring techniques that may be appropriate for recording behaviour and quantifying biodiversity.
There may be extra costs related to your course for items such as books, stationery, printing, photocopying, binding and general subsistence on trips and visits. Following graduation, you may need to pay a subscription to a professional body for some chosen careers.
Specific additional costs for studying at Lancaster are listed below.
College fees
Lancaster is proud to be one of only a handful of UK universities to have a collegiate system. Every student belongs to a college, and all students pay a small College Membership Fee which supports the running of college events and activities. Students on some distance-learning courses are not liable to pay a college fee.
For students starting in 2025, the fee is £40 for undergraduates and research students and £15 for students on one-year courses.
Computer equipment and internet access
To support your studies, you will also require access to a computer, along with reliable internet access. You will be able to access a range of software and services from a Windows, Mac, Chromebook or Linux device. For certain degree programmes, you may need a specific device, or we may provide you with a laptop and appropriate software - details of which will be available on relevant programme pages. A dedicated IT support helpdesk is available in the event of any problems.
The University provides limited financial support to assist students who do not have the required IT equipment or broadband support in place.
For most taught postgraduate applications there is a non-refundable application fee of £40. We cannot consider applications until this fee has been paid, as advised on our online secure payment system. There is no application fee for postgraduate research applications.
For some of our courses you will need to pay a deposit to accept your offer and secure your place. We will let you know in your offer letter if a deposit is required and you will be given a deadline date when this is due to be paid.
The fee that you pay will depend on whether you are considered to be a home or international student. Read more about how we assign your fee status.
If you are studying on a programme of more than one year’s duration, tuition fees are reviewed annually and are not fixed for the duration of your studies. Read more about fees in subsequent years.
Scholarships and bursaries
You may be eligible for the following funding opportunities, depending on your fee status and course. You will be automatically considered for our main scholarships and bursaries when you apply, so there's nothing extra that you need to do.
Unfortunately no scholarships and bursaries match your selection, but there are more listed on scholarships and bursaries page.
A number of our programmes offer bursaries for excellent students applying for specific degree schemes. These bursaries include the Heatherlea and Peter John Vincent prizes.
You will find yourself taking advantage of several laboratory facilities at Lancaster Environment Centre. There are our £4.4 million Teaching Labs, for example, as well as specialist facilities for Environmental Chemistry, Noble Gas, and Plant and Soil Ecology.
Research Facilities
There are no fewer than 15 purpose-built glasshouse modules, 16 controlled environment plant growth rooms, 4 solar domes based at the Hazelrigg Weather Station and a suite of ultraviolet radiation research facilities that can truly claim to be world-class.
Field Sites
You could find yourself working at a range of catchment science sites across England and Wales, including the local River Eden Valley, or they can travel much further afield to the tropical forests of the Amazon and Borneo.
Cutting-Edge Technologies
You can be trained to use a range of equipment, such as our Stable Isotope Ratio Mass Spectrometer Facility, X-ray CT Scanner, Magnetometer or the LI-COR Portable Photosynthesis System, which has the capacity to measure plant gas exchange with exceptional speed and precision.
Rich Data Resources
Dedicated support staff with expertise in GIS, statistics, modelling, information technology and programming are available to provide specialist training in all aspects of data acquisition, processing and analysis.
Important Information
The information on this site relates primarily to 2025/2026 entry to the University and every effort has been taken to ensure the information is correct at the time of publication.
The University will use all reasonable effort to deliver the courses as described, but the University reserves the right to make changes to advertised courses. In exceptional circumstances that are beyond the University’s reasonable control (Force Majeure Events), we may need to amend the programmes and provision advertised. In this event, the University will take reasonable steps to minimise the disruption to your studies. If a course is withdrawn or if there are any fundamental changes to your course, we will give you reasonable notice and you will be entitled to request that you are considered for an alternative course or withdraw your application. You are advised to revisit our website for up-to-date course information before you submit your application.
More information on limits to the University’s liability can be found in our legal information.
Our Students’ Charter
We believe in the importance of a strong and productive partnership between our students and staff. In order to ensure your time at Lancaster is a positive experience we have worked with the Students’ Union to articulate this relationship and the standards to which the University and its students aspire. View our Charter and other policies.