2019
DOI: 10.21468/scipostphyslectnotes.11
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An introduction to spontaneous symmetry breaking

Abstract: Perhaps the most important aspect of symmetry in physics is the idea that a state does not need to have the same symmetries as the theory that describes it. This phenomenon is known as spontaneous symmetry breaking. In these lecture notes, starting from a careful definition of symmetry in physics, we introduce symmetry breaking and its consequences. Emphasis is placed on the physics of singular limits, showing the reality of symmetry breaking even in small-sized systems. Topics covered include Nambu-Goldstone … Show more

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Cited by 129 publications
(171 citation statements)
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“…The Mermin-Wagner-Hohenberg-Coleman theorem does not prohibit type-B SSB from occurring in onedimensional systems at zero temperature [5,31,32]. We can therefore confirm the generality of the analytic results of the Lieb-Mattis model in Section VI using numerical results for a one-dimensional ferrimagnetic Heisenberg chain.…”
Section: Numerical Resultssupporting
confidence: 61%
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“…The Mermin-Wagner-Hohenberg-Coleman theorem does not prohibit type-B SSB from occurring in onedimensional systems at zero temperature [5,31,32]. We can therefore confirm the generality of the analytic results of the Lieb-Mattis model in Section VI using numerical results for a one-dimensional ferrimagnetic Heisenberg chain.…”
Section: Numerical Resultssupporting
confidence: 61%
“…Two broken symmetry generators lead to one quadratically dispersing Goldstone mode and a gapped partner mode. Finally, type-B systems do not suffer from the Coleman theorem and are stable in one dimension [5,31,32] (although both type-A and type-B systems are subject to the Mermin-Wagner-Hohenberg theorem that forbids SSB in two or lower dimensions at finite temperature [5,31]). There seems to be only one essential difference between general ("ferri") type-B SSB and the peculiar case of the ferromagnet: the latter is the same as the classical ferromagnet, whereas the ferrimagnet is a classical Néel state dressed with quantum corrections [27].…”
Section: Discussionmentioning
confidence: 99%
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