Brendon W. Lovett, Ahsan Nazir
Published 2009-03-16Version 1
Coherence is a familiar concept in physics: It is the driving force behind wavelike phenomena such as the diffraction of light. Moreover, wave-particle duality implies that all quantum objects can exhibit coherence, and this quantum coherence is crucial to understanding the behaviour of a plethora of systems. In this article, which is written at an undergraduate level, we shall briefly introduce what is meant by coherence in a well-known classical setting, before going on to describe its quantum version. We will show that coherence is important in describing the properties of solid-state nanosystems, and especially quantum dots. Simple experiments that reveal the coherent nature of matter - and how this leads to some very powerful applications - will be described. Finally, we shall discuss the fragility of coherence and shall introduce a method for describing decoherence in open quantum systems.
Comments: Invited review paper at an introductory level, aimed at an undergraduate audience. To appear in European Journal of Physics, Special feature on Nanotechnology. 14 pages, 4 figures
Journal: European Journal of Physics 30 S89 (2009)
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