In mathematics, and in particular gauge theory and complex geometry, a Hermitian Yang–Mills connection (or Hermite–Einstein connection) is a Chern connection associated to an inner product on a holomorphic vector bundle over a Kähler manifold that satisfies an analogue of Einstein's equations: namely, the contraction of the curvature 2-form of the connection with the Kähler form is required to be a constant times the identity transformation. Hermitian Yang–Mills connections are special examples of Yang–Mills connections, and are often called instantons.
The Kobayashi–Hitchin correspondence proved by Donaldson, Uhlenbeck and Yau asserts that a holomorphic vector bundle over a compact Kähler manifold admits a Hermitian Yang–Mills connection if and only if it is slope polystable.
Hermite–Einstein connections arise as solutions of the Hermitian Yang–Mills equations. These are a system of partial differential equations on a vector bundle over a Kähler manifold, which imply the Yang–Mills equations. Let
A
E
X
n
| 0,2 | |
| \begin{align} &F | |
| A |
=0\\ &FA ⋅ \omega=λ(E)\operatorname{Id}, \end{align}
for some constant
λ(E)\inC
FA\wedge\omegan-1=(FA ⋅ \omega)\omegan.
A
FA
| 0,2 | |
| F | |
| A |
=0
| 2,0 | |
| F | |
| A |
=0
X
λ(E)
\begin{align} \deg(E) &:=\intXc1(E)\wedge\omegan-1\\ &=
| i | |
| 2\pi |
\intX\operatorname{Tr}(FA)\wedge\omegan-1\\ &=
| i | |
| 2\pi |
\intX\operatorname{Tr}(FA ⋅ \omega)\omegan. \end{align}
Since
FA ⋅ \omega=λ(E)\operatorname{Id}E
E
λ(E)=-
| 2\pii | |
| n!\operatorname{Vol |
(X)}\mu(E),
where
\mu(E)
E
\mu(E)=
| \deg(E) | |
| \operatorname{rank |
(E)},
and the volume of
X
\omegan/n!
Due to the similarity of the second condition in the Hermitian Yang–Mills equations with the equations for an Einstein metric, solutions of the Hermitian Yang–Mills equations are often called Hermite–Einstein connections, as well as Hermitian Yang–Mills connections.
The Levi-Civita connection of a Kähler–Einstein metric is Hermite–Einstein with respect to the Kähler–Einstein metric. (These examples are however dangerously misleading, because there are compact Einstein manifolds, such as the Page metric on
{CP}2\#\overline{CP}2
When the Hermitian vector bundle
E
| 0,2 | |
| F | |
| A |
=0
E
h
h
The Hermite–Einstein condition on Chern connections was first introduced by . These equation imply the Yang–Mills equations in any dimension, and in real dimension four are closely related to the self-dual Yang–Mills equations that define instantons. In particular, when the complex dimension of the Kähler manifold
X
2
| 2 | |
| Λ | |
| + |
=Λ2,0 ⊕ Λ0,2 ⊕ \langle\omega\rangle,
| 2 | |
| Λ | |
| - |
=\langle\omega\rangle\perp\subsetΛ1,1
E
| 0,2 | |
| F | |
| A |
=
| 2,0 | |
| F | |
| A |
=FA ⋅ \omega=0
| + | |
| F | |
| A |
=0
A