F-Yang–Mills equations

In differential geometry, the ${\displaystyle F}$-Yang–Mills equations (or ${\displaystyle F}$-YM equations) are a generalization of the Yang–Mills equations. Its solutions are called ${\displaystyle F}$-Yang–Mills connections (or ${\displaystyle F}$-YM connections). Simple important cases of ${\displaystyle F}$-Yang–Mills connections include exponential Yang–Mills connections using the exponential function for ${\displaystyle F}$ and ${\displaystyle p}$-Yang–Mills connections using ${\displaystyle p}$ as exponent of a potence of the norm of the curvature form similar to the ${\displaystyle p}$-norm. Also often considered are Yang–Mills–Born–Infeld connections (or YMBI connections) with positive or negative sign in a function ${\displaystyle F}$ involving the square root. This makes the Yang–Mills–Born–Infeld equation similar to the minimal surface equation.

Let ${\displaystyle F:{ℝ}_0^{+}\to {ℝ}_0^{+}}$ be a strictly increasing ${\displaystyle C^2}$ function (hence with ${\displaystyle F^{\prime }>0}$) and ${\displaystyle F(0)=0}$. Let:^[1]

${\displaystyle d_F:=\underset{t\ge 0}{\sup }\frac{t{F}^{\prime }(t)}{F(t)}.}$

Since ${\displaystyle F}$ is a ${\displaystyle C^2}$ function, one can also consider the following constant:^[2]

${\displaystyle d_{F^{\prime }}=\underset{t\ge 0}{\sup }\frac{t{F}^{″}(t)}{F^{\prime }(t)}.}$

Let ${\displaystyle G}$ be a compact Lie group with Lie algebra ${\displaystyle 𝔤}$ and ${\displaystyle E\twoheadrightarrow B}$ be a principal ${\displaystyle G}$-bundle with an orientable Riemannian manifold ${\displaystyle B}$ having a metric ${\displaystyle g}$ and a volume form ${\displaystyle {\mathrm{vol}}_g}$. Let ${\displaystyle \mathrm{Ad}(E):=E{\times }_G𝔤\twoheadrightarrow B}$ be its adjoint bundle. ${\displaystyle {\mathrm{\Omega }}_{\mathrm{Ad}}^1(E,𝔤)\cong {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$ is the space of connections,^[3] which are either under the adjoint representation ${\displaystyle \mathrm{Ad}}$ invariant Lie algebra–valued or vector bundle–valued differential forms. Since the Hodge star operator ${\displaystyle \star }$ is defined on the base manifold ${\displaystyle B}$ as it requires the metric ${\displaystyle g}$ and the volume form ${\displaystyle {\mathrm{vol}}_g}$, the second space is usually used.

The ${\displaystyle F}$-Yang–Mills action functional is given by:^[2][4]

${\displaystyle {\mathrm{YM}}_F:{\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))\to ℝ,{\mathrm{YM}}_F(A):=\underset{B}{\int }F(\frac{1}{2}\Vert F_A{\Vert }^2)\mathrm{d}{\mathrm{vol}}_g.}$

For a flat connection ${\displaystyle A\in {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$ (with ${\displaystyle F_A=0}$), one has ${\displaystyle {\mathrm{YM}}_F(A)=F(0)\mathrm{vol}(M)}$. Hence ${\displaystyle F(0)=0}$ is required to avert divergence for a non-compact manifold ${\displaystyle B}$, although this condition can also be left out as only the derivative ${\displaystyle F^{\prime }}$ is of further importance.

A connection ${\displaystyle A\in {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$ is called ${\displaystyle F}$-Yang–Mills connection, if it is a critical point of the ${\displaystyle F}$-Yang–Mills action functional, hence if:

${\displaystyle \frac{\mathrm{d}}{\mathrm{d}t}{\mathrm{YM}}_F(A(t)){|}_{t=0}=0}$

for every smooth family ${\displaystyle A:(-\epsilon ,\epsilon )\to {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$ with ${\displaystyle A(0)=A}$. This is the case iff the ${\displaystyle F}$-Yang–Mills equations are fulfilled:^[2][4]

${\displaystyle {\mathrm{d}}_A\star \left(F^{\prime }(\frac{1}{2}\Vert F_A{\Vert }^2)F_A\right)=0.}$

For a ${\displaystyle F}$-Yang–Mills connection ${\displaystyle A\in {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$, its curvature ${\displaystyle F_A\in {\mathrm{\Omega }}^2(B,\mathrm{Ad}(E))}$ is called ${\displaystyle F}$-Yang–Mills field.

A ${\displaystyle F}$-Yang–Mills connection/field with:^[1][2][4]

• ${\displaystyle F(t)=t}$ is just an ordinary Yang–Mills connection/field.
• ${\displaystyle F(t)=\exp (t)}$ (or ${\displaystyle F(t)=\exp (t)-1}$ for normalization) is called (normed) exponential Yang–Mills connection/field. In this case, one has ${\displaystyle d_{F^{\prime }}=\mathrm{\infty }}$. The exponential and normed exponential Yang–Mills action functional are denoted with ${\displaystyle {\mathrm{YM}}_{\mathrm{e}}}$ and ${\displaystyle {\mathrm{YM}}_{\mathrm{e}}^0}$ respectively.^[5]
• ${\displaystyle F(t)=\frac{1}{p}(2t{)}^{\frac{p}{2}}}$ is called ${\displaystyle p}$-Yang–Mills connection/field. In this case, one has ${\displaystyle d_{F^{\prime }}=\frac{p}{2}-1}$. Usual Yang–Mills connections/fields are exactly the ${\displaystyle 2}$-Yang–Mills connections/fields. The ${\displaystyle p}$-Yang–Mills action functional is denoted with ${\displaystyle {\mathrm{YM}}_p}$.
• ${\displaystyle F(t)=\sqrt{1-2t}-1}$ or ${\displaystyle F(t)=\sqrt{1+2t}-1}$ is called Yang–Mills–Born–Infeld connection/field (or YMBI connection/field) with negative or positive sign respectively. In these cases, one has ${\displaystyle d_{F^{\prime }}=\mathrm{\infty }}$ and ${\displaystyle d_{F^{\prime }}=0}$ respectively. The Yang–Mills–Born–Infeld action functionals with negative and positive sign are denoted with ${\displaystyle {\mathrm{YMBI}}^{-}}$ and ${\displaystyle {\mathrm{YMBI}}^{+}}$ respectively. The Yang–Mills–Born–Infeld equations with positive sign are related to the minimal surface equation:

  ${\displaystyle {\mathrm{d}}_A\frac{\star F_A}{\sqrt{1+\Vert F_A{\Vert }^2}}=0.}$

Analogous to (weakly) stable Yang–Mills connections, one can define (weakly) stable ${\displaystyle F}$-Yang–Mills connections. A ${\displaystyle F}$-Yang–Mills connection ${\displaystyle A\in {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$ is called stable if:

${\displaystyle \frac{{\mathrm{d}}^2}{\mathrm{d}{t}^2}{\mathrm{YM}}_F(A(t)){|}_{t=0}>0}$

for every smooth family ${\displaystyle A:(-\epsilon ,\epsilon )\to {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$ with ${\displaystyle A(0)=A}$. It is called weakly stable if only ${\displaystyle \ge 0}$ holds. A ${\displaystyle F}$-Yang–Mills connection, which is not weakly stable, is called unstable.^[4] For a (weakly) stable or unstable ${\displaystyle F}$-Yang–Mills connection ${\displaystyle A\in {\mathrm{\Omega }}^1(B,\mathrm{Ad}(E))}$, its curvature ${\displaystyle F_A\in {\mathrm{\Omega }}^2(B,\mathrm{Ad}(E))}$ is furthermore called a (weakly) stable or unstable ${\displaystyle F}$-Yang–Mills field.

• For a Yang–Mills connection with constant curvature, its stability as Yang–Mills connection implies its stability as exponential Yang–Mills connection.^[5]
• Every non-flat exponential Yang–Mills connection over ${\displaystyle S^n}$ with ${\displaystyle n\ge 5}$ and:

  ${\displaystyle \Vert F_A\Vert \le \sqrt{\frac{n-4}{2}}}$

is unstable.^[2][4]

• Every non-flat Yang–Mills–Born–Infeld connection with negative sign over ${\displaystyle S^n}$ with ${\displaystyle n\ge 5}$ and:

  ${\displaystyle \Vert F_A\Vert \le \sqrt{\frac{n-4}{n-2}}}$

is unstable.^[2]

• All non-flat ${\displaystyle F}$-Yang–Mills connections over ${\displaystyle S^n}$ with ${\displaystyle n>4(d_{F^{\prime }}+1)}$ are unstable.^[2][4] This result includes the following special cases:
  • All non-flat Yang–Mills connections with positive sign over ${\displaystyle S^n}$ with ${\displaystyle n>4}$ are unstable.^[6][7][8] James Simons presented this result without written publication during a symposium on "Minimal Submanifolds and Geodesics" in Tokyo in September 1977.
  • All non-flat ${\displaystyle p}$-Yang–Mills connections over ${\displaystyle S^n}$ with ${\displaystyle n>2p}$ are unstable.
  • All non-flat Yang–Mills–Born–Infeld connections with positive sign over ${\displaystyle S^n}$ with ${\displaystyle n>4}$ are unstable.
• For ${\displaystyle 0\le d_{F^{\prime }}\le \frac{1}{6}}$, every non-flat ${\displaystyle F}$-Yang–Mills connection over the Cayley plane ${\displaystyle F_4/\mathrm{Spin}(9)}$ is unstable.^[4]

• Template:Cite book

• Bi-Yang–Mills equations, modification of the Yang–Mills equation

Template:Reflist

• F-Yang-Mills equation at the nLab