Yang–Mills–Higgs equations

In mathematics, the Yang–Mills–Higgs equations are a set of non-linear partial differential equations for a Yang–Mills field, given by a connection, and a Higgs field, given by a section of a vector bundle (specifically, the adjoint bundle). These equations are

{\begin{aligned}D_{A}*F_{A}+[\Phi ,D_{A}\Phi ]&=0,\\D_{A}*D_{A}\Phi &=0\end{aligned}}

with a boundary condition

\lim _{|x|\rightarrow \infty }|\Phi |(x)=1

where

A is a connection on a vector bundle,

D_A is the exterior covariant derivative,

F_A is the curvature of that connection,

Φ is a section of that vector bundle,

∗ is the Hodge star, and

[·,·] is the natural, graded bracket.

These equations are named after Chen Ning Yang, Robert Mills, and Peter Higgs. They are very closely related to the Ginzburg–Landau equations, when these are expressed in a general geometric setting.

M.V. Goganov and L.V. Kapitanskii have shown that the Cauchy problem for hyperbolic Yang–Mills–Higgs equations in Hamiltonian gauge on 4-dimensional Minkowski space have a unique global solution with no restrictions at the spatial infinity. Furthermore, the solution has the finite propagation speed property.

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Lagrangian

The equations arise as the equations of motion of the Lagrangian density

Yang–Mills–Higgs Lagrangian density

${\mathcal {L}}=-{\frac {1}{4}}\left\langle F_{\mu \nu },F^{\mu \nu }\right\rangle +{\frac {1}{2}}\left\langle D_{\mu }\phi ,D^{\mu }\phi \right\rangle -V(\phi )$

where $\langle \cdot ,\cdot \rangle$ is an invariant symmetric bilinear form on the adjoint bundle. This is sometimes written as ${\text{tr}}$ due to the fact that such a form can arise from the trace on ${\mathfrak {g}}$ under some representation; in particular here we are concerned with the adjoint representation, and the trace on this representation is the Killing form.

For the particular form of the Yang–Mills–Higgs equations given above, the potential $V(\phi )$ is vanishing. Another common choice is $V(\phi )={\frac {1}{2}}m^{2}\langle \phi ,\phi \rangle$ , corresponding to a massive Higgs field.

This theory is a particular case of scalar chromodynamics where the Higgs field $\phi$ is valued in the adjoint representation as opposed to a general representation.

References

M.V. Goganov and L.V. Kapitansii, "Global solvability of the initial problem for Yang-Mills-Higgs equations", Zapiski LOMI 147,18–48, (1985); J. Sov. Math, 37, 802–822 (1987).

Quantum field theories

Theories

Models

Regular	Born–Infeld Euler–Heisenberg Ginzburg–Landau Non-linear sigma Proca Quantum electrodynamics Quantum chromodynamics Quartic interaction Scalar electrodynamics Scalar chromodynamics Soler Yang–Mills Yang–Mills–Higgs Yukawa
Low dimensional	2D Yang–Mills Bullough–Dodd Gross–Neveu Schwinger Sine-Gordon Thirring Thirring–Wess Toda
Conformal	2D free massless scalar Liouville Minimal Polyakov Wess–Zumino–Witten
Supersymmetric	Wess–Zumino N = 1 super Yang–Mills Seiberg–Witten Super QCD
Superconformal	6D (2,0) ABJM N = 4 super Yang–Mills
Supergravity	Higher dimensional N = 8 Pure 4D N = 1
Topological	BF Chern–Simons
Particle theory	Chiral Fermi MSSM Nambu–Jona-Lasinio NMSSM Standard Model Stueckelberg

See also:

Template:Quantum mechanics topics

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This page was last edited on 10 September 2023, at 13:02

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Lagrangian

See also

References