Cosmology and the distant Universe
This module introduces the science of cosmology, which aims to answer fundamental questions about the nature, history and future of the Universe. You’ll develop skills to use the mathematical tools and physical models needed to describe the Universe on the largest scales and examine how today’s stars and galaxies came to exist. You’ll also explore a variety of phenomena of the distant Universe, from the earliest galaxies to black-hole jets and gamma-ray bursts. You’ll use a range of observational evidence to test theoretical ideas throughout the module; at times, you’ll come up against the limits of our current understanding.
What you will study
The module introduces the fundamental concepts of modern cosmology and selected topics in extragalactic astrophysics. You’ll develop skills in applying the ideas of cosmology and the astrophysics of the distant Universe through problem-solving and using and interpreting observational evidence. You’ll explore how this evidence supports current theories about the Universe and its evolution and gain an understanding of current open questions and the limitations of our knowledge.
The module comprises printed books, supporting practical activities and online content.
Cosmology provides a thorough introduction to modern cosmology, beginning with an overview of current understanding to provide context for the more specialised topics that follow. You’ll then explore the basic concepts and mathematical language of special and general relativity, learning how these underpin our ability to describe the geometry of the Universe. The module introduces the metric describing the geometry of the Universe and the Friedmann equations that describe its expansion. You’ll learn how a small set of cosmological parameters define spacetime’s past and future evolution, then explore the key observational evidence supporting the current model and how observations measure these fundamental parameters. In later parts, you’ll follow a history of the Universe from the earliest particle interactions to the formation of structure via gravitational collapse and, eventually, the birth of stars and galaxies.
Three Python-based practical activities support this part of the module, providing hands-on experience working with cosmological models and observations.
The Distant Universe provides a series of in-depth study topics in extragalactic astrophysics, linked to each other and Cosmology by themes of relativity and the interaction of matter and radiation. You’ll examine how we find and study the first galaxies and learn about their impact on their surroundings. You’ll then consider in more depth how to use the technique of gravitational lensing – the bending of light by massive objects – to learn about distant galaxies and more nearby objects. You’ll also learn about the dynamic processes in the Universe’s most massive structures, galaxy clusters. Finally, the module introduces the topic of high-energy astrophysics; you’ll learn about observations and models of extreme phenomena, including jets from supermassive black holes and gamma-ray bursts.
Two further Python-based practical activities support Book 2 The Distant Universe.
You will learn
You’ll build on your mathematical, physics and astronomy knowledge to further develop your understanding of fundamental concepts in physics and astronomy in the specific context of cosmology and astrophysical phenomena associated with the distant Universe.
Entry requirements
There are no formal entry requirements for this module.
At 快猫视频, we believe education should be open to all, so we provide high-quality university education to anyone who wishes to realise their ambitions and fulfil their potential.
Even though there are no entry requirements, you’ll need an appropriate knowledge of mathematics and physics obtained through:
- OU level 1 and 2 study
- equivalent work at another higher education institution.
Preparatory work
We recommend you’ve completed:
Plus:
This module includes Python coding activities, which assume a good computing ability. If you’ve passed SXPS288, your coding experience should be appropriate. Otherwise, we recommend you undertake some Python preparation. Once a student, you can access the ‘Programming for Physical Sciences’ resource page with self-study material.
What's included
We provide printed module books.
You’ll also 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 will need
A scientific calculator or equivalent capability.
Computing requirements
You’ll need broadband internet access and a desktop or laptop computer with an up-to-date version of Windows (10 or 11) or macOS Ventura or higher.
Any additional software will be provided or is generally freely available.
To join in spoken conversations in tutorials, we recommend a wired headset (headphones/earphones with a built-in microphone).
Our module websites comply with web standards, and any modern browser is suitable for most activities.
Our OU Study mobile app will operate on all current, supported versions of Android and iOS. It’s not available on Kindle.
It’s also possible to access some module materials on a mobile phone, tablet device or Chromebook. However, as you may be asked to install additional software or use certain applications, you’ll also require a desktop or laptop, as described above.