Last modified: 25 Mar 2016 11:32
This course gives insight into the Universe and looks at how modern physics impacts our world. From special relativity we will examine time dilation, length contraction and E=mc2. Quantum mechanical concepts will be introduced, such as matter waves and the uncertainty principle. Particle physics is then outlined followed by the design and purpose of the LHC. The course discusses the Big Bang theory and important cosmological issues, such as the effects of general relativity, Olbers’ paradox, dark matter and dark energy. Large-scale astronomy to be covered includes stellar and galactic evolutions and ‘exotic’ objects such as quasars and black holes.
Study Type | Undergraduate | Level | 2 |
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Term | Second Term | Credit Points | 15 credits (7.5 ECTS credits) |
Campus | None. | Sustained Study | No |
Co-ordinators |
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In the first part of the course, we discuss general "Modern Physics". The twin subjects of relativity and quantum mechanics have had an impact right across the sciences. The course discusses why these topics emerged from classical physics, outlines what they are about and some of their fundamental results. From special relativity we will examine time dilation, mass increase, length contraction and of course E=mc2 and the implications of this equation. The development of quantum mechanics will be followed, leading to such key results as the (implications of the) Schrodinger Wave equation and the Heisenberg uncertainty principle. We will then go on to learn about the basics of nuclear and particle physics, leading to the design and purpose of the LHC.
The course also addresses some philosophical issues raised by the question "What is science?" and what distinguishes it from other fields of knowledge. It discusses the Big Bang theory of the origin of the Universe and how this theory makes predictions that can be tested by observation, such as the cosmic microwave background and the relative abundance of light elements in the Universe. The course looks at several cosmological issues, such as the role of General Relativity, Olbers paradox, dark matter and dark energy. Large-scale astronomy is discussed including the evolution of galaxies, different kinds of stars and their evolution and the presence of "exotic" objects such as quasars and black holes.
Information on contact teaching time is available from the course guide.
1st Attempt: 1 two-hour multiple choice examination (60%); in-course assessment (40%) comprising two group presentations and a short summary essay.
Resit: 1 two-hour multiple choice examination (60%). The in-course assessment will be carried forward, although there is the opportunity to resubmit the short summary essay (worth 10%).
Problem solving will be tackled during tutorials and help and feedback will be given individually.
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