Editing Quantum field theory (section)

====Spontaneous symmetry-breaking====
{{Main|Spontaneous symmetry breaking}}

[[Spontaneous symmetry breaking]] is a mechanism whereby the symmetry of the Lagrangian is violated by the system described by it.{{r|peskin|page1=347}}

To illustrate the mechanism, consider a linear [[sigma model]] containing {{math|''N''}} real scalar fields, described by the Lagrangian density:
:<math>\mathcal{L} = \frac 12 \left(\partial_\mu\phi^i\right)\left(\partial^\mu\phi^i\right) + \frac 12 \mu^2 \phi^i\phi^i - \frac{\lambda}{4} \left(\phi^i\phi^i\right)^2,</math>
where {{math|''μ''}} and {{math|''λ''}} are real parameters. The theory admits an {{math|[[orthogonal group|O(''N'')]]}} global symmetry:
:<math>\phi^i \to R^{ij}\phi^j,\quad R\in\mathrm{O}(N).</math>
The lowest energy state (ground state or vacuum state) of the classical theory is any uniform field {{math|''ϕ''<sub>0</sub>}} satisfying
:<math>\phi_0^i \phi_0^i = \frac{\mu^2}{\lambda}.</math>
Without loss of generality, let the ground state be in the {{math|''N''}}-th direction:
:<math>\phi_0^i = \left(0,\cdots,0,\frac{\mu}{\sqrt{\lambda}}\right).</math>
The original {{math|''N''}} fields can be rewritten as:
:<math>\phi^i(x) = \left(\pi^1(x),\cdots,\pi^{N-1}(x),\frac{\mu}{\sqrt{\lambda}} + \sigma(x)\right),</math>
and the original Lagrangian density as:
:<math>\mathcal{L} = \frac 12 \left(\partial_\mu\pi^k\right)\left(\partial^\mu\pi^k\right) + \frac 12 \left(\partial_\mu\sigma\right)\left(\partial^\mu\sigma\right) - \frac 12 \left(2\mu^2\right)\sigma^2 - \sqrt{\lambda}\mu\sigma^3 - \sqrt{\lambda}\mu\pi^k\pi^k\sigma - \frac{\lambda}{2} \pi^k\pi^k\sigma^2 - \frac{\lambda}{4}\left(\pi^k\pi^k\right)^2,</math>
where {{math|''k'' {{=}} 1, ..., ''N'' − 1}}. The original {{math|O(''N'')}} global symmetry is no longer manifest, leaving only the [[subgroup]] {{math|O(''N'' − 1)}}. The larger symmetry before spontaneous symmetry breaking is said to be "hidden" or spontaneously broken.{{r|peskin|page1=349–350}}

[[Goldstone's theorem]] states that under spontaneous symmetry breaking, every broken continuous global symmetry leads to a massless field called the Goldstone boson. In the above example, {{math|O(''N'')}} has {{math|''N''(''N'' − 1)/2}} continuous symmetries (the dimension of its [[Lie algebra]]), while {{math|O(''N'' − 1)}} has {{math|(''N'' − 1)(''N'' − 2)/2}}. The number of broken symmetries is their difference, {{math|''N'' − 1}}, which corresponds to the {{math|''N'' − 1}} massless fields {{math|''π<sup>k</sup>''}}.{{r|peskin|page1=351}}

On the other hand, when a gauge (as opposed to global) symmetry is spontaneously broken, the resulting Goldstone boson is "eaten" by the corresponding gauge boson by becoming an additional degree of freedom for the gauge boson. The Goldstone boson equivalence theorem states that at high energy, the amplitude for emission or absorption of a longitudinally polarized massive gauge boson becomes equal to the amplitude for emission or absorption of the Goldstone boson that was eaten by the gauge boson.{{r|peskin|page1=743–744}}

In the QFT of [[ferromagnetism]], spontaneous symmetry breaking can explain the alignment of [[magnetic dipole]]s at low temperatures.{{r|zee|page1=199}} In the Standard Model of elementary particles, the [[W and Z bosons]], which would otherwise be massless as a result of gauge symmetry, acquire mass through spontaneous symmetry breaking of the [[Higgs boson]], a process called the [[Higgs mechanism]].{{r|peskin|page1=690}}