Let $M$ be a complex manifold, $R^{\nabla}$ be the curvature operator for connections $\nabla$. Consider a polynomial function $f:\operatorname M_n(\mathbb{C})\to\mathbb{C}$. For the gauge group $\operatorname{GL}_n(\mathbb{C})$, if $f(A)=f(gAg^{-1})$ where $A \in \operatorname M_n(\mathbb{C})$ and $g \in \operatorname{GL}_n(\mathbb{C})$, then $f$ is said to be an invariant polynomial function. Let $I^k(\operatorname M_n(\mathbb{C}))$ be the set of all such polynomials of degree $k$. Also, $\bigoplus_{k\geq0}I^{k}(\operatorname M_n(\mathbb{C}))=I(\operatorname M_n(\mathbb{C}))$.

We shall need $\phi_n(A)=det(A)$, $n>1$, and $\phi_1(A)=Tr(A)$.

Define a global differential form ($2k$-form) $f(R^{\nabla}) \in \mathbb{A}^{2k}(M)$. If we have the de Rham cohomology group $H^{2k}(M)$, then the Weil homomorphism is defined as the map $\omega:I(\operatorname M_n(\mathbb{C}))\to \bigoplus_{k\geq 0}H^{2k}(M)$.

The Chern forms $c_{i}(R^{\nabla})=\phi_{i}(\frac{\sqrt{-1}}{2\pi}R^{\nabla})$.

For the complex vector bundle $(\mathbb{E},\pi,M)$, where $\mathbb{E}$ is the total space, the Chern classes are defined as $c_{i}(\mathbb{E}) \in H^{2k}(M)$.

Therefore $c_{i}(\mathbb{E})\mathrel{:=}\omega(c_{i}(R^{\nabla}))=[c_{i}(R^{\nabla})]$ (de Rham cohomology class).

The Chern forms $c_{i}(R^{\nabla}) \in \mathbb{A}^{2i}(\mathbb{E})$.

$\mathbb{A}^{2i}(\mathbb{E})$ is sheaf of smooth $\mathbb{E}$-valued $2i$ for $M$.

Cohomology groups are very important in geometry for understanding the invariants that can be defined on manifolds. That is, the transformations that keep some special properties of the manifold and which analogous to the gauge transformations in physics.

Chern classes are special type of cohomology classes. If the first Chern class vanishes for a particular manifold, then it must be a Ricci-flat manifold. For example the Calabi–Yau manifolds (they have lots of other special properties, e.g., trivial canonical bundle, etc.).

But what do the higher Chern classes mean? What uses are those higher cohomology classes corresponding to the higher Chern classes of?

Let $M$ be a complex manifold, $R^{\nabla}$ be the curvature operator for connections $\nabla$. Consider a polynomial function $f:\operatorname M_n(\mathbb{C})\to\mathbb{C}$. For the gauge group $\operatorname{GL}_n(\mathbb{C})$, if $f(A)=f(gAg^{-1})$ where $A \in \operatorname M_n(\mathbb{C})$ and $g \in \operatorname{GL}_n(\mathbb{C})$, then $f$ is said to be an invariant polynomial function. Let $I^k(\operatorname M_n(\mathbb{C}))$ be the set of all such polynomials of degree $k$. Also, $\bigoplus_{k\geq0}I^{k}(\operatorname M_n(\mathbb{C}))=I(\operatorname M_n(\mathbb{C}))$.

We shall need $\phi_n(A)=det(A)$, $n>1$, and $\phi_1(A)=Tr(A)$.

Define a global differential form ($2k$-form) $f(R^{\nabla}) \in \mathbb{A}^{2k}(M)$. If we have the de Rham cohomology group $H^{2k}(M)$, then the Weil homomorphism is defined as the map $\omega:I(\operatorname M_n(\mathbb{C}))\to \bigoplus_{k\geq 0}H^{2k}(M)$.

The Chern forms $c_{i}(R^{\nabla})=\phi_{i}(\frac{\sqrt{-1}}{2\pi}R^{\nabla})$.

For the complex vector bundle $(\mathbb{E},\pi,M)$, where $\mathbb{E}$ is the total space, the Chern classes are defined as $c_{i}(\mathbb{E}) \in H^{2k}(M)$.

Therefore $c_{i}(\mathbb{E})\mathrel{:=}\omega(c_{i}(R^{\nabla}))=[c_{i}(R^{\nabla})]$ (de Rham cohomology class).

The Chern forms $c_{i}(R^{\nabla}) \in \mathbb{A}^{2i}(\mathbb{E})$.

$\mathbb{A}^{2i}(\mathbb{E})$ is sheaf of smooth $\mathbb{E}$-valued $2i$ forms on $M$.

Cohomology groups are very important in geometry for understanding the invariants that can be defined on manifolds. That is, the transformations that keep some special properties of the manifold and which analogous to the gauge transformations in physics.

Chern classes are special type of cohomology classes. If the first Chern class vanishes for a particular manifold, then it must be a Ricci-flat manifold. For example the Calabi–Yau manifolds (they have lots of other special properties, e.g., trivial canonical bundle, etc.).

But what do the higher Chern classes mean? What uses are those higher cohomology classes corresponding to the higher Chern classes of?

Let M be a complex manifold, $R^{\nabla}$ be the curvature operator for connections $\nabla$. Consider a polynomial function $f:M_n(\mathbb{C})\to\mathbb{C}$ . For the gauge group $GL_n(\mathbb{C})$, if $f(A)=f(gAg^{-1})$

where $A$ $\epsilon$ $M_n(\mathbb{C})$ and $g$ $\epsilon$ $GL_n(\mathbb{C})$

Then $f$ is said to be an invariant polynomial function. Let $I^{K}(M_n(\mathbb{C}))$ be the set of all such polynomials of degree $k$. Also, $\oplus_{k\geq0}I^{k}(M_n(\mathbb{C}))=I(M_n(\mathbb{C}))$

We shall need $\phi_n(A)=det(A),n>1$ and $\phi_1(A)=Tr(A)$

Define a global differential form (2k-form) $f(R^{\nabla})$ $\epsilon$ $\mathbb{A}^{2k}(M)$ If we have the de Rham cohomology group $H^{2k}(M)$

  the Weil homomorphism is defined as the map $\omega:I(M_n(\mathbb{C}))\to \oplus_{k\geq 0}H^{2k}(M)$

The chern forms $c_{i}(R^{\nabla})=\phi_{i}(\frac{\sqrt{-1}}{2\pi}R^{\nabla})$

For the complex vector bundle $(\mathbb{E},\pi,M)$ where $\mathbb{E}$ is the total space  , the chern classes are defined as $c_{i}(\mathbb{E})$ $\epsilon$ $H^{2k}(M)$

therefore $c_{i}(\mathbb{E}):=\omega(c_{i}(R^{\nabla}))=[c_{i}(R^{\nabla})]$ (de Rham cohomology class)

The chern forms $c_{i}(R^{\nabla})$ $\epsilon$ $\mathbb{A}^{2i}(\mathbb{E})$

$\mathbb{A}^{2i}(\mathbb{E})$ is sheaf of smooth $\mathbb{E}$ valued $2i$ for M.

Cohomology groups are very important in geometry for understanding the invariants that can be defined on manifolds. That is, the transformations that keep some special properties of the manifold and which analogous to the gauge transformations in physics.

Chern classes are special type of cohomology classes. If the first chern class vanishes for a particular manifold the then it must be a Ricci-flat manifold. For example the Calabi Yau manifolds(they have lots of other special properties e.g. trivial canonical bundle etc)

But what do the higher Chern classes mean? What uses are those higher cohomology classes corresponding to the higher chern classes of  ?

Let $M$ be a complex manifold, $R^{\nabla}$ be the curvature operator for connections $\nabla$. Consider a polynomial function $f:\operatorname M_n(\mathbb{C})\to\mathbb{C}$. For the gauge group $\operatorname{GL}_n(\mathbb{C})$, if $f(A)=f(gAg^{-1})$ where $A \in \operatorname M_n(\mathbb{C})$ and $g \in \operatorname{GL}_n(\mathbb{C})$, then $f$ is said to be an invariant polynomial function. Let $I^k(\operatorname M_n(\mathbb{C}))$ be the set of all such polynomials of degree $k$. Also, $\bigoplus_{k\geq0}I^{k}(\operatorname M_n(\mathbb{C}))=I(\operatorname M_n(\mathbb{C}))$.

We shall need $\phi_n(A)=det(A)$, $n>1$, and $\phi_1(A)=Tr(A)$.

Define a global differential form ($2k$-form) $f(R^{\nabla}) \in \mathbb{A}^{2k}(M)$. If we have the de Rham cohomology group $H^{2k}(M)$, then the Weil homomorphism is defined as the map $\omega:I(\operatorname M_n(\mathbb{C}))\to \bigoplus_{k\geq 0}H^{2k}(M)$.

The Chern forms $c_{i}(R^{\nabla})=\phi_{i}(\frac{\sqrt{-1}}{2\pi}R^{\nabla})$.

For the complex vector bundle $(\mathbb{E},\pi,M)$, where $\mathbb{E}$ is the total space, the Chern classes are defined as $c_{i}(\mathbb{E}) \in H^{2k}(M)$.

Therefore $c_{i}(\mathbb{E})\mathrel{:=}\omega(c_{i}(R^{\nabla}))=[c_{i}(R^{\nabla})]$ (de Rham cohomology class).

The Chern forms $c_{i}(R^{\nabla}) \in \mathbb{A}^{2i}(\mathbb{E})$.

$\mathbb{A}^{2i}(\mathbb{E})$ is sheaf of smooth $\mathbb{E}$-valued $2i$ for $M$.

Cohomology groups are very important in geometry for understanding the invariants that can be defined on manifolds. That is, the transformations that keep some special properties of the manifold and which analogous to the gauge transformations in physics.

Chern classes are special type of cohomology classes. If the first Chern class vanishes for a particular manifold, then it must be a Ricci-flat manifold. For example the Calabi–Yau manifolds  (they have lots of other special properties, e.g., trivial canonical bundle, etc.).

But what do the higher Chern classes mean? What uses are those higher cohomology classes corresponding to the higher Chern classes of?