Quantum field theory
This is a module framework. It can be viewed online or downloaded as a zip file.
Last taught in Spring Semester 2006
A compilation of fourteen lectures in PDF format on the subject of quantum field theory. This module is suitable for 3rd or 4th year undergraduate and postgraduate level learners.
Suitable for year 3/4 undergraduate and postgraduate study.
Dr Kirill Krasnov, School of Mathematical Sciences
Dr Kirill Krasnov is a Lecturer at the University of Nottingham. After studying physic
Quantum Information Processing
Quantum Information Processing aims at harnessing quantum physics to conceive and build devices that could dramatically exceed the capabilities of today's "classical" computation and communciation systems. In this course, we will introduce the basic concepts of this rapidly developing field. Study Goals: To understand the operation, potential, and limitations of the main theoretical results (algorithms, error correction, communication)
To be able to use the formalism of quantum information (uni
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Quantum Information Processing
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Quantum Field Theory
The first free comprehensive textbook on quantum (and classical) field theory. The approach is pragmatic, rather than traditional or artistic: It includes practical techniques, such as the 1/N expansion (color ordering) and spacecone (spinor helicity), and diverse topics, such as supersymmetry and general relativity, as well as introductions to supergravity and strings. The PDF version can be more convenient than paper books, with Web links and a clickable outline (contents) window.
Quantum Mechanics
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Quantum Wave Interference
When do photons, electrons, and atoms behave like particles and when do they behave like waves? Watch waves spread out and interfere as they pass through a double slit, then get detected on a screen as tiny dots. Use quantum detectors to explore how measurements change the waves and the patterns they produce on the screen.
Quantum Tunneling
Watch quantum "particles" tunnel through barriers. Explore the properties of the wave functions that describe these particles.
Quantum Bound States
Explore the properties of quantum "particles" bound in potential wells. See how the wave functions and probability densities that describe them evolve (or don't) over time. Teacher's guide available.
Optical Quantum Control
Explore an active area of research in optical physics: producing designer pulse shapes to achieve specific purposes, such as breaking apart a molecule. Carefully create the perfect shaped pulse to break apart a molecule by individually manipulating the colors of light that make up a pulse.
Quantum Doughnuts
Research led by the University of Warwick has found a way to use doughnut shaped by-products of quantum dots to slow and even freeze light, opening up a wide range of possibilities from reliable and effective light based computing to the possibility of "slow glass".
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The restless Universe introduces you to major achievements and figures in the history of physics, from Copernicus to Einstein and beyond. The route from classical to quantum physics will be laid out for you without recourse to challenging mathematics but with the fundamental features of theories and discoveries described in sufficient detail to whet your appetite for further physics study.
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The restless Universe introduces you to major achievements and figures in the history of physics, from Copernicus to Einstein and beyond. The route from classical to quantum physics will be laid out for you without recourse to challenging mathematics but with the fundamental features of theories and discoveries described in sufficient detail to whet your appetite for further physics study.
Quantum 4
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Quantum 3
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Quantum 2
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Quantum
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Quantum Microeconomics
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