nLab stable Yang-Mills-Higgs pair

Redirected from "stable Yang-Mills-Higgs pairs".

Contents

Context

Quantum Field Theory

Differential cohomology

Idea
Basics
Definition
Properties
See also
References

Idea

A (weakly) stable Yang-Mills-Higgs pair (or (weakly) stable YMH connection) is a Yang-Mills-Higgs pair, around which the Yang-Mills-Higgs action functional is positive or even strictly positively curved. Yang-Mills-Higgs pairs are critical points of the Yang-Mills-Higgs action functional, where the first variational derivative vanishes. For (weakly) stable Yang-Mills connections, the second derivative is additionally required to be positive or even strictly positive.

Basics

Consider

$G$ a Lie group and $\mathfrak{g}$ its Lie algebra,
$X$ an orientable Riemannian manifold with Riemannian metric $g$ and volume form $vol_g$ ,
$P\twoheadrightarrow X$ a principal $G$ -bundle and $Ad(P)\coloneqq P\times_G\mathfrak{g}\twoheadrightarrow B$ its adjoint bundle,
$\Phi\in\Omega^0(X,Ad(P))\cong\Gamma^\infty(X,Ad(P))$ a smooth section,
$A\in\Omega_{\operatorname{Ad}}^1(P,\mathfrak{g})$ (affine space over $\Omega^1(X,Ad(P))$ ) a principal connection,
$F_A\coloneqq\mathrm{d}A+\frac{1}{2}[A\wedge A]\in\Omega^2(X,Ad(P))$ its curvature. If $A$ is a Yang-Mills connection, $F_A$ is also called Yang-Mills field.

Definition

The Yang-Mills-Higgs action functional (or YMH action functional) is given by:

YMH\colon \Omega^1(X,Ad(P))\times\Gamma^\infty(X,Ad(P))\rightarrow\mathbb{R}, YMH(A,\Phi) \coloneqq\int_X\|F_A\|^2+\|\mathrm{d}_A\Phi\|^2\mathrm{d}vol_g.

$A$ and $\Phi$ are called a stable Yang-Mills-Higgs pair (or stable YMH pair) iff:

\frac{\mathrm{d}^2}{\mathrm{d}t^2}\operatorname{YMH}(\alpha(t),\varphi(t))\vert_{t=0} \gt 0

for all smooth families $\alpha\colon(-\varepsilon,\varepsilon)\rightarrow\Omega^1(B,\operatorname{Ad}(E))$ and $\varphi\colon(-\varepsilon,\varepsilon)\rightarrow\Gamma^\infty(X,Ad(P))$ with $\alpha(0)=A$ and $\varphi(0)=\Phi$ . It is called weakly stable if only $\geq 0$ holds. For comparison, the condition for a Yang-Mills-Higgs pair (or YMH pair) is:

\frac{\mathrm{d}}{\mathrm{d}t}YMH(\alpha(t),\varphi(t))\vert_{t=0} =0.

(Hu & Hu 15, Cheng 21, Definition 3.1, Han, Jin & Wen 23)

Theorem

(Formula for Yang–Mills–Higgs stability) Let $\alpha\colon(-\varepsilon,\varepsilon)\rightarrow\Omega^1(X,Ad(P))$ be a path with $A=\alpha(0)$ , $B=\alpha'(0)$ and $C=\alpha''(0)$ and let $\varphi\colon(-\varepsilon,\varepsilon)\rightarrow\Omega^1(X,Ad(P))$ be a path with $\Phi=\varphi(0)$ , $\Psi=\varphi'(0)$ and $\Omega=\varphi''(0)$ , then:

\begin{aligned} \frac{\mathrm{d}^2}{\mathrm{d}t^2}YMH(\alpha(t),\varphi(t))\vert_{t=0} &=\int_X\|\mathrm{d}_A B\|^2 +\|\mathrm{d}_A \Psi+[B,\Phi]\|^2 +\langle\underbrace{\delta_A F_A-[\mathrm{d}_A\Phi,\Phi]}_{YMH},C\rangle \\ &+\langle\underbrace{\delta_A \mathrm{d}_A\Phi}_{YMH},\Omega\rangle +\langle F_A,[B\wedge B]\rangle +2\langle\mathrm{d}_A\Phi,[B,\Psi]\rangle. \end{aligned}

The Yang-Mills-Higgs equations are

\delta_A F_A-[\mathrm{d}_A \Phi,\Phi]=0

as well as

\delta_A \mathrm{d}_A \Phi=0

and therefore the formula simplifies for a Yang-Mills-Higgs pair

(A,\Phi)

. In this case it also becomes independent of

C

and

\Omega

Proof

For the calculations for the first term see stable Yang-Mills connection. One has the following derivatives for the covariant derivative:

\begin{aligned} \frac{\mathrm{d}}{\mathrm{d}t}\mathrm{d}_{\alpha(t)}\varphi(t) &=\frac{\mathrm{d}}{\mathrm{d}t}\left( \mathrm{d}\varphi(t) +[\alpha(t),\varphi(t)] \right) \\ &=\mathrm{d}\varphi'(t) +[\alpha(t),\varphi'(t)] +[\alpha'(t),\varphi(t)] =\mathrm{d}_{\alpha(t)}\varphi'(t) +[\alpha'(t),\varphi(t)]; \end{aligned}

\begin{aligned} \frac{\mathrm{d}^2}{\mathrm{d}t^2}d_{\alpha(t)}\varphi(t) &=\mathrm{d}\varphi''(t) +[\alpha(t),\varphi''(t)] +2[\alpha'(t),\varphi'(t)] +[\alpha''(t),\varphi(t)] \\ &=\mathrm{d}_{\alpha(t)}\varphi''(t) +2[\alpha'(t),\varphi'(t)] +[\alpha''(t),\varphi(t)], \end{aligned}

which combine together into the following second derivative for the additional part of the Yang-Mills-Higgs action functional:

\begin{aligned} \frac{\mathrm{d}^2}{\mathrm{d}t^2}(YMH-YM)(\alpha(t),\varphi(t))\vert_{t=0} &=\int_X\left\|\frac{\mathrm{d}}{\mathrm{d}t}\mathrm{d}_{\alpha(t)}\varphi(t)\right\|^2 +\left\langle\mathrm{d}_{\alpha(t)}\varphi(t),\frac{\mathrm{d}^2}{\mathrm{d}t^2}\mathrm{d}_{\alpha(t)}\varphi(t)\right\rangle\mathrm{d}vol_g\vert_{t=0} \\ &=\int_X\|\mathrm{d}_{\alpha(t)}\varphi'(t)+[\alpha'(t),\varphi(t)]\|^2 \\ &+\left\langle \mathrm{d}_{\alpha(t)}\varphi(t),\mathrm{d}_{\alpha(t)}\varphi''(t) +2[\alpha'(t),\varphi'(t)] +[\alpha''(t),\varphi(t)]\right\rangle\mathrm{d}vol_g \end{aligned}

Since the first and second term are always positive, leaving both out directly implies:

Corollary

If $A\in\Omega^1(X,Ad(P))$ and $\Phi\in\Gamma^\infty(X,Ad(P))$ are a Yang-Mills-Higgs pair with:

\int_X\langle F_A,[B\wedge B]\rangle +2\langle\mathrm{d}_A\Phi,[B,\Psi]\rangle\mathrm{d}vol_g \gt 0\;\text{(or}\geq 0\text{)}

for all $B\in\Omega^1(X,Ad(P))$ and $\Psi\in\Gamma^\infty(X,Ad(P))$ , then it is stable (or weakly stable).

Properties

Theorem

Let $(A,\Phi)$ be a weakly stable YMH pair on $S^n$ .

If $n=4$ , then $\mathrm{d}_A\star F_A=0$ (meaning $A$ is a YM connection), $\mathrm{d}_A\Phi=0$ and $\|\Phi\|=1$ .
If $n\geq 5$ , then $F_A=0$ (meaning $A$ is flat), $\mathrm{d}_A\Phi=0$ and $\|\Phi\|=1$ .

(Han, Jin & Wen 23)

References

Zhi Hu, Sen Hu; Degenerate and Stable Yang-Mills-Higgs Pair (2015) [arxiv:1502.01791]
Da Rong Cheng, Stable Solutions to the Abelian Yang–Mills–Higgs Equations on $S^2$ and $T^2$ (2021), Journal of Geometric Analysis 31, pp. 9551–9572, [doi:10.1007/s12220-021-00619-y]
Xiaoli Han, Xishen Jin, Yang Wen; Stability and energy identity for Yang-Mills-Higgs pairs (2023), Journal of Mathematical Physics 64, [arxiv:2303.00270 doi:10.1063/5.0130905]

nLab stable Yang-Mills-Higgs pair

Context

Quantum Field Theory

Concepts

Theorems

States and observables

Operator algebra

Local QFT

Perturbative QFT

Differential cohomology

Ingredients

Connections on bundles

Higher abelian differential cohomology

Higher nonabelian differential cohomology

Fiber integration

Application to gauge theory

Contents

Idea

Basics

Definition

Theorem

Proof

Corollary

Properties

Theorem

See also

References