Geoscience with a Year of International Study

Core Modules

Year 1

• Physics and Chemistry of the Earth

  In this module you will develop an understanding of basic concepts in chemistry and physics and how to apply these to geological processes. You will look at atoms and atomic structure, the periodic table of elements, reactions, equations, geochemical analysis, the composition of the earth, interpretation of phase diagrams, solubility of minerals, weathering and the hydrological cycle. You will also consider Newton’s Laws, kinematics, circular motion, planetary orbits, gravity, magnetism, electricity, resistivity, stress, strain, seismicity, isostasy, radioactivity, and geochronology.

• Earth Scientists Toolkit

  In this module you develop an understanding of the skills required to practice geology in the field, carrying out a series of activities in South Devon and Pembrokeshire. You will learn to describe and interpret the origin of sedimentary, igneous and metamorphic rocks and how to prepare a geological map and cross-section using standard symbols. You will examine stereographic projections, sedimentary logging, the construction of stratigraphic columns for the identification of rocks, and the analysis of structural features using stereonets.

• Evolving Earth

  This module introduces the 4.6 billion-year history of our Evolving Earth and provides you with the skills to interpret that history. The module is subdivided into two complimentary streams that closely integrate. One stream (palaeontology) considers the story of life from its origin to the rise and fall of the dinosaurs, concluding with our own recent human evolution. It focuses on major events in evolution, and introduces you to the key concepts including systematic palaeontology, palaeoecology, palaeobiology, evolution, and taphonomy. The other stream (sedimentology) considers earth surface processes and palaeoenvironments and teaches you how to recognise the changing environments through time using techniques including rock classification, textural analysis, facies analysis and graphic logging, palaeoflow analysis, and stratigraphy. Because life and environments have co-evolved and are co-dependent, palaeontology and sedimentology need to be taught in close parallel, providing you with a powerful synthetic understanding of how our Earth has evolved in the past and continues to change in the future.

• Dynamic Planet

  Earth is a dynamic and evolving planet with a record of plate tectonic and environmental change over its 4.6 billion year history. This module explores the geological structure and the processes that shape our planet and other planets within our solar system, from the planetary heat engine that powers plate motion and leads to the surface expression of these forces in volcanoes and earthquakes, to the use of maps, minerals and rocks to unlock the story in the rocks beneath our feet.

• Human Interaction with the Earth

  With the adoption of the Paris Agreement and the recent COP26, a seismic societal shift towards issues related to sustainability and climate change is taking place globally. The next generation of geoscientists are now required to understand the complex interrelations between human activities and a changing Earth system. With this module, students will explore key themes at the core of human-Earth interaction such as anthropogenic climate change, geohazards, environmental pollution, and sustainable exploitation of energy resources and energy-critical elements.

• Academic Integrity

  This module will describe the key principles of academic integrity, focusing on university assignments. Plagiarism, collusion and commissioning will be described as activities that undermine academic integrity, and the possible consequences of engaging in such activities will be described. Activities, with feedback, will provide you with opportunities to reflect and develop your understanding of academic integrity principles.

   

Year 2

• Stratigraphy and Past Sedimentary Environments

  In this module you will develop an understanding of the key events in the history of life and their environmental impact using the fossil and sedimentary record. You will analyse fossil assemblages using stratigraphic principles such as absolute dating, lithostratigraphy, biostratigraphy and sequence stratigraphy. You will consider how to interpret sedimentary rocks, and examine the importance of fossil assemblages in the interpretation of events in earth history.

• Geological Evolution and Deep Time Synthesis

  In this module you will develop an understanding of the geological evolution of the British Isles, interpreting regional geological history from geological maps. You will learn to describe rock specimens and examine how palaeoenvironments can be reconstructed using case studies. You will also consider the application of stratigraphic techniques and use evidence from several different fields of geology to evaluate competing hypotheses for geological evolution.

• Igneous and Metamorphic Geology

  In this module you will further develop your understanding of igneous and metamorphic geology. You will look at the characteristics and origins of alkaline igneous rocks, the nature and controls on metamorphic reactions, and the links between metamorphism and tectonic processes. You will consider hand specimen and thin section techniques for study of minerals and igneous and metamorphic rocks, and examine analytical approaches to the interpretation of metamorphic rocks, including the quantification of metamorphic rates and processes.

• Geochemistry

  In this module you will develop an understanding of advanced chemical concepts relevant to the Earth Sciences. You will focus on isotope geochemistry and consider techniques that are directly applicable in most geological contexts. You will attend practical classes and conduct a small project involving the analysis and interpretation of a real geochemical dataset.

• Earth Scientists Mapping Toolkit

  In this module you will develop advanced geological field skills. You will carry out a series of activities in an area of igneous and metamorphic rocks, and in an area of sedimentary rocks. You will learn to describe and interpret the origin of the rock types in the field and will prepare a geological map and cross-section using standard symbols. You will analyse structural features using stereonets, and infer the geological history of a region through the construction of scaled cross-sections through structurally complex terrains.

Year 3

• Year of International Study

  This year will be spent studying abroad. Royal Holloway has a number of formal partnerships with institutions in Europe and further afield. Students should be aware that placement at a host institution is a competitive process involving an application to the university abroad and this process is supported by Royal Holloway. This year forms an integral part of the degree programme. Marks obtained for courses taken at the institution abroad will be credited towards their degree.

• Geological Mapping 1
• Techniques in Earth Sciences

  The module aims to teach students advanced level key geological and transferable skills. Data Handling - a lecture and practical course on retrieval and handling of geological data which revises and extends numerical skills introduced in years 1 and 2. Presentation skills – presentation exercise to improve spoken, visual and other aspects of communication in geology. Advanced Field Skills - includes data collection, teamwork and site investigations.

   

Year 4

• Independent Geoscience Project

  Under the guidance of a departmental supervisor, you will design and execute an independent research project which will be submitted for examination as a report of 45 pages. The project will utilise data collected in the field or the laboratory and may involve an industrial placement. Field-based projects will normally be based on 7-10 days of fieldwork. Data handling using statistical techniques must be integrated into the project. You will use departmental facilities to supplement data already acquired or produce their main database. Emphasis will be placed on ensuring that topics are properly designed before the commencement of the project and that appropriate progress is being made throughout both terms. Selection and outline of agreed topic and agreed deadline will be presented on a form to be countersigned by member of Academic Staff who will act as a supervisor.

• Formation and Evolution of the continents
• Evolution of the Modern Earth

  This course will integrate sedimentary, palaeontological, oceanographic and atmospheric information from the geological and modern record to understand the evolution of the modern Earth. Students will investigate the climate record through geologic time and what it can tell us about the future challenges of climate change, utilising a varied range of paleoclimatic proxies from both paleontology and sedimentology and looking at the range of climate data. They will explore the links between climate, tectonics and sedimentary systems. They will assess the intimate relationship between the evolution of land life and the evolution of the atmosphere.

• Field and Research Skills

  The aim is to equip MSci students (and potentially new PhD students) with the skills and techniques to undertake research. The course will include scientific ethics, the intelligent and efficient design of research or experiments, including how to capture, store and deal with data and meta-data, project planning, how to publicize your science, press release, video, outreach etc, an Introduction to Unix/Linux and a scripting language such as python i.e. how to do many things to a large number of files or large files and how to run them efficiently. Data reduction and interrogation with Igor or R or python with plotting publication ready data to maximum effect. Uncertainty in scientific measurement and modelling and how to propagate it. An introduction to basic electronics and interfacing your computer to an experiment and log/capture data, and ending with image capture and analysis.

• Geological Mapping 2

Optional Modules

There are a number of optional course modules available during your degree studies. The following is a selection of optional course modules that are likely to be available. Please note that although the College will keep changes to a minimum, new modules may be offered or existing modules may be withdrawn, for example, in response to a change in staff. Applicants will be informed if any significant changes need to be made.

Year 1

• Environmental Issues with Maths

  In this module you will develop an understanding of the fundamentals of environmental geology, including the connection between ecology and geology, the rates of geological processes, and the structure of the Earth. You will look at natural hazards such as earthquakes, volcanism, tsunamis, landslides and flooding. You will also consider the origin and usage of water and energy resources and examine the geological tools available to study climate change. You will learn how to manipulate algebraic equations and expressions, gaining familiarity with several types of charts, diagrams, and projections commonly used in geological sciences, such as log-log plots and stereonets.

• Petroleum Geology with Maths

Year 2

• Sedimentary Basin Analysis

  In this module you will develop an understanding of how to classify sedimentary basins according to their tectonic mode of formation. You will learn to explain and illustrate the basic processes of subsidence and uplift in basins formed by extension, and flexural loading of, the lithosphere. You will also consider how characteristic patterns of sedimentary facies and stratigraphic architecture relate to different basin types and the tectonic processes that formed them, examining the tectonosedimentary history of stratigraphic successions in outcrop and subsurface data.

• Geohazards

  In this module you will develop an understanding of the hazards associated with geological activity, their causes, and approaches to risk management. You will look at volcanoes, earthquakes, and radon, and the hazards associated with the exploitation of geological resources and associated anthropogenic activity, including asbestos, the mining industry, and contaminated land. You will examine a variety of geological and geochemical data, and learn to interpret and analyse these in order to make scientifically justified decisions as to the level of risk.

• Applied Geophysics

  In this module you will develop an understanding of the theory and practice of seismic, gravity, magnetic and resistivity surveying. You will consider the methods used to manipulate, analyse, and display geophysical data to solve geological exploration problems, and examine the strengths and weaknesses of the different data types.

• Computational Earth Sciences

  In this module you will develop an understanding of how computation tools are used to read, create, analyse, and visualise digital earth science data. You will learn to use python, a popular scripting language, to read and manipulate data from digital files, and look at digital mapping techniques, using data to plot 2D and 3D maps. You will consider how to fit linear data and analyse the goodness of fit using statistical analysis tools, and examine how to produce simple models of geological processes using algebraic expression, such as generating models for seismic travel time curves, major element concentration during magma crystallization, sedimentary basin thickness, and other similar geological phenomena.

• Structural Analysis and Remote Sensing

  In this module you will develop an understanding of how to analyse geological structures in terms of the deformational mechanisms and tectonic stresses that have produced them. You will look at brittle failure in rocks, fracture types and propagation, and consider the relationship between principal stresses and geologic structures on small and regional scales. You will examine remotely sensed continental and marine data sets, and use imagery available in Google Earth for tectonic analysis.

Year 4

• All modules are core