The relativistic Universe
If you are interested in using quantitative physical methods to understand relativistic and high-energy processes in the Universe, and already have a good background in OU level 2 maths, physics and astronomy, then this is the module for you. This module comprises three parts that present, in turn, the theoretical basis for modern cosmology, described by Einstein’s special and general theories of relativity; cosmological observations of the local and distant Universe that are used to understand its structure and evolution; and high-energy phenomena in the Universe including interacting binary stars, active galactic nuclei and gamma-ray bursts.
What you will study
This module will give you a good understanding of relativistic astrophysics and cosmology, including both their theoretical underpinnings and their observational consequences. It is a mathematical module that builds on skills and concepts you will have developed by studying maths, physics and astronomy at a level equivalent to OU level 2 modules. The module makes full use of tools in the OU’s Virtual Learning Environment (VLE) and internet-based resources are used throughout.
Part 1, Relativity, Gravitation and Cosmology, is based around a book which allows you to develop an understanding of special and general relativity and apply this knowledge to the structure and evolution of the Universe as a whole. You will learn how a metric is used to describe mathematically a space-time (including unrealistic two- and three-dimensional models, as well as possibly more realistic four-dimensional space-times). You will then develop an understanding of Einstein’s theory of general relativity as a metric theory of gravity, including the role of the Einstein field equations, some examples of specific solutions and the current status of a range of ‘tests’ of general relativity. Finally you will learn about the existence, nature and implications of cosmological solutions to the Einstein field equations subject to the assumption of large-scale homogeneity and isotropy (including the effect of a cosmological constant/uniform dark energy density).
Part 2, Observational Cosmology, is based around a book which allows you to learn about the various observational techniques and measurements that provide a picture of the structure and evolution of the Universe on the largest scales. You will acquire knowledge and understanding of statistical cosmological techniques as well as current relativistic cosmological models and the observational evidence for them. You will learn about the bulk properties of local and distant galaxies and the physical inferences that can be made from them.
Part 3, Extreme Environment Astrophysics, is based around a book which focuses on the role of accretion in the presence of strong gravitational fields and the physics of relativistic objects, including white dwarfs, neutron stars and black holes. You will learn the physics of the main high-energy phenomena arising in compact and accreting systems as well as the main physical processes occurring in, and parameters of, accreting systems at small and large scales. You will study the astrophysics of interacting binary stars, active galaxies, accretion discs, their outbursts and outflows, and gamma-ray bursts, and will also discover the methods used in the measurement and characterisation of accretion flow properties. Your study of this part will allow you to develop basic concepts of hydrodynamics, thermodynamics and plasma physics.
This is an OU level 3 module that builds on study skills and subject knowledge acquired from previous studies at OU levels 1 and 2. It is intended for students who have recent experience of higher education in a related subject at this level.
The module is designed to follow Astronomy (S282), Remote experiments in physics and space (SXPS288) (or its predecessor SXPA288) and Mathematical methods (MST224). The parts of MST224 relating to ordinary and partial differential equations and matrices, and the parts of S282 relating to galaxies and cosmology are especially important.
It is essential that you establish whether or not your background and experience give you a sound basis on which to tackle the module, since students who are appropriately prepared have the best chance of completing their studies successfully. The Science Faculty has produced a booklet Are You Ready For S382/S383? to help you to decide whether you already have the recommended background knowledge or experience to start the module or whether you need some extra preparation.
If you have any doubt about the suitability of the module, please speak to an adviser.
As a result of taking the Are you ready for ...? test, you may find that you need to study a further module or modules before embarking on S383. If this is not possible, you may choose to spend time studying relevant background material. For this purpose we have produced a ‘Book 0’ for S383 (and the related module S382) entitled An introduction to astrophysics and cosmology, which you may download as a PDF. This document covers the recommended background knowledge and skills that we expect students to possess before embarking on S383. If you need to study all the maths, physics and astronomy background contained within this Book 0, we estimate it will require about 40–60 hours of study. It is not a replacement for taking the appropriate OU level 2 modules, but it will serve to fill the gaps in your knowledge in many cases.
You'll have access to a module website, which includes:
- a week-by-week study planner
- course-specific module materials
- audio and video content
- assignment details and submission section
- online tutorial access.
You'll also be provided with three printed module books and a DVD-ROM.
You will need
Basic scientific calculator.
A computing device with a browser and broadband internet access is required for this module. Any modern browser will be suitable for most computer activities. Functionality may be limited on mobile devices.
Any additional software will be provided, or is generally freely available. However, some activities may have more specific requirements. For this reason, you will need to be able to install and run additional software on a device that meets the requirements below.
- A desktop or laptop computer with an up-to-date version of Windows
- The screen must have a resolution of at least 1024 pixels horizontally and 768 pixels vertically.
To join in the spoken conversation in our online rooms we recommend a headset (headphones or earphones with an integrated microphone).
Our Skills for OU study website has further information including computing skills for study, computer security, acquiring a computer and Microsoft software offers for students.