Difference between revisions of "Chow ring"
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$$f_*(f^*(y)\cdot x) = y\cdot f_*(x), \quad x \in CH(X), \quad y \in CH(Y)$$ | $$f_*(f^*(y)\cdot x) = y\cdot f_*(x), \quad x \in CH(X), \quad y \in CH(Y)$$ | ||
| − | The Chow ring is the domain of values for the classical theory of Chern classes of vector bundles (cf. | + | The Chow ring is the domain of values for the classical theory of Chern classes of vector bundles (cf. {{Cite|Ha}}). More precisely, if $E$ is a locally free sheaf of rank $r$ over a variety $X$, if $\pi:P(E) \to X$ is its projectivization and if $\zeta \in \CH^1(P(E))$ is the class of the divisor corresponding to the invertible sheaf $\mathcal{O}_{P(E)}(1)$, then $\pi^*$ is injective and the Chow ring $\CH(P(E))$ may be identified with the quotient ring of the polynomial ring $\CH(X)[\zeta]$ by the ideal generated by the polynomial |
$$\zeta^r -c_1(E)\zeta^{r-1}+\cdots + (-1)^r c_r(E).$$ | $$\zeta^r -c_1(E)\zeta^{r-1}+\cdots + (-1)^r c_r(E).$$ | ||
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In the case of a variety over the field of complex numbers, there is a homomorphism $\CH(X) \to \mathrm{H}(X,\mathbb Z)$ into the singular cohomology ring that preserves the degree and commutes with the inverse-image and direct-image homomorphisms. | In the case of a variety over the field of complex numbers, there is a homomorphism $\CH(X) \to \mathrm{H}(X,\mathbb Z)$ into the singular cohomology ring that preserves the degree and commutes with the inverse-image and direct-image homomorphisms. | ||
| − | If $X$ is a singular quasi-projective variety, then its Chow ring $\CH(X)$ is defined as the direct limit of rings $\CH(X)=\varinjlim \CH(Y)$ over all morphisms $f:X \to Y$, where $Y$ is non-singular. One obtains a contravariant functor into the category of graded rings, satisfying the projection formula (cf. | + | If $X$ is a singular quasi-projective variety, then its Chow ring $\CH(X)$ is defined as the direct limit of rings $\CH(X)=\varinjlim \CH(Y)$ over all morphisms $f:X \to Y$, where $Y$ is non-singular. One obtains a contravariant functor into the category of graded rings, satisfying the projection formula (cf. {{Cite|Fu}}). |
====References==== | ====References==== | ||
| − | + | {| | |
| − | + | |- | |
| − | + | |valign="top"|{{Ref|Ch}}||valign="top"| "Anneaux de Chow et applications", ''Sem. Chevalley'' (1958) {{MR|}} {{ZBL|0098.13101}} | |
| + | |- | ||
| + | |valign="top"|{{Ref|Fu}}||valign="top"| W. Fulton, "Rational equivalence on singular varieties" ''Publ. Math. IHES'', '''45''' (1975) pp. 147–167 {{MR|0404257}} {{ZBL|0332.14002}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Ha}}||valign="top"| R. Hartshorne, "Algebraic geometry", Springer (1977) {{MR|0463157}} {{ZBL|0367.14001}} | ||
| + | |- | ||
| + | |} | ||
====Comments==== | ====Comments==== | ||
| − | For $X$ a Noetherian scheme (or ring), let $K_n(X)$ denote the $n$-th $K$-group of (the category of) finitely-generated projective modules over $X$; cf. [[Algebraic K-theory|Algebraic K-theory]]. Let $\mathcal{K}$ denote the sheaf obtained by sheafifying (in the Zariski topology) the pre-sheaf $U \mapsto K_n(U)$ where $U$ runs through the open (affine) subschemes of $X$. One then has the Bloch formula | + | For $X$ a Noetherian scheme (or ring), let $K_n(X)$ denote the $n$-th $K$-group of (the category of) finitely-generated projective modules over $X$; cf. [[Algebraic K-theory|Algebraic K-theory]]. Let $\mathcal{K}$ denote the sheaf obtained by sheafifying (in the Zariski topology) the pre-sheaf $U \mapsto K_n(U)$ where $U$ runs through the open (affine) subschemes of $X$. One then has the Bloch formula {{Cite|Bl}} |
$$\CH^p(X) \simeq H^p(X, \mathcal{K}_p)$$ | $$\CH^p(X) \simeq H^p(X, \mathcal{K}_p)$$ | ||
| − | providing a link between the Chow groups of $X$ and the cohomology of $X$ with values in the $\mathcal{K}$-sheaves of $X$. Using results on the algebraic K-theory of fields, | + | providing a link between the Chow groups of $X$ and the cohomology of $X$ with values in the $\mathcal{K}$-sheaves of $X$. Using results on the algebraic K-theory of fields, {{Cite|MeSu}}, this can be used to obtain results on Chow groups, in particular on $\CH^2$, {{Cite|Co}}. |
Cf. [[Sheaf theory|Sheaf theory]] for the notions of sheafification, pre-sheaf, sheaf, and cohomology with values in a sheaf. | Cf. [[Sheaf theory|Sheaf theory]] for the notions of sheafification, pre-sheaf, sheaf, and cohomology with values in a sheaf. | ||
====References==== | ====References==== | ||
| − | + | {| | |
| + | |- | ||
| + | |valign="top"|{{Ref|Bl}}||valign="top"| S. Bloch, "Lectures on algebraic cycles", Dept. Math. Duke Univ. (1980) {{MR|0558224}} {{ZBL|0436.14003}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Co}}||valign="top"| J.-L. Colliot-Thélène, "Hilbert's theorem 90 for $K_2$ with application to the Chow groups of rational surfaces" ''Inv. Math.'', '''71''' (1983) pp. 1–20 | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Fu2}}||valign="top"| W. Fulton, "Intersection theory", Springer (1984) {{MR|0735435}} {{MR|0732620}} {{ZBL|0541.14005}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|MeSu}}||valign="top"| A.S. Merkur'ev, A.A. Suslin, "K-cohomology of Severi–Brauer varieties and norm residue homomorphism" ''Math. USSR Izv.'', '''21''' (1983) pp. 307–340 ''Izv. Akad. Nauk SSSR Ser. Mat.'', '''46''' : 5 (1982) pp. 1011–1046 {{MR|}} {{ZBL|0525.18008}} {{ZBL|0525.18007}} | ||
| + | |- | ||
| + | |} | ||
Revision as of 20:49, 23 April 2012
$
\newcommand{\CH}{\mathrm{CH}}
$
The ring of rational equivalence classes of algebraic cycles (cf. Algebraic cycle) on a non-singular quasi-projective algebraic variety. Multiplication in this ring is defined in terms of intersections of cycles (cf. Intersection theory).
The Chow ring $\CH(X)=\bigoplus_{i\geq 0} \CH^i(X)$ of a variety $X$ is a graded commutative ring, where $\CH^i(X)$ denotes the group of classes of cycles of codimension $i$. In earlier publications, the notation $\mathrm{A}(X)$ is sometimes used instead of $\CH(X)$.
For a morphism $f:X \to Y$ the inverse-image homomorphism $f^*:\CH(Y) \to \CH(X)$ is a homomorphism of rings, and for $f$ proper, the direct-image homomorphism $f_*: \CH(X)\to \CH(Y)$ is a homomorphism of $\CH(Y)$-modules. This means that there is a projection formula:
$$f_*(f^*(y)\cdot x) = y\cdot f_*(x), \quad x \in CH(X), \quad y \in CH(Y)$$
The Chow ring is the domain of values for the classical theory of Chern classes of vector bundles (cf. [Ha]). More precisely, if $E$ is a locally free sheaf of rank $r$ over a variety $X$, if $\pi:P(E) \to X$ is its projectivization and if $\zeta \in \CH^1(P(E))$ is the class of the divisor corresponding to the invertible sheaf $\mathcal{O}_{P(E)}(1)$, then $\pi^*$ is injective and the Chow ring $\CH(P(E))$ may be identified with the quotient ring of the polynomial ring $\CH(X)[\zeta]$ by the ideal generated by the polynomial
$$\zeta^r -c_1(E)\zeta^{r-1}+\cdots + (-1)^r c_r(E).$$
The coefficient $c_k(E)\in \CH^k(X)$ is called the $k$-th Chern class of the locally free sheaf $E$.
In the case of a variety over the field of complex numbers, there is a homomorphism $\CH(X) \to \mathrm{H}(X,\mathbb Z)$ into the singular cohomology ring that preserves the degree and commutes with the inverse-image and direct-image homomorphisms.
If $X$ is a singular quasi-projective variety, then its Chow ring $\CH(X)$ is defined as the direct limit of rings $\CH(X)=\varinjlim \CH(Y)$ over all morphisms $f:X \to Y$, where $Y$ is non-singular. One obtains a contravariant functor into the category of graded rings, satisfying the projection formula (cf. [Fu]).
References
| [Ch] | "Anneaux de Chow et applications", Sem. Chevalley (1958) Zbl 0098.13101 |
| [Fu] | W. Fulton, "Rational equivalence on singular varieties" Publ. Math. IHES, 45 (1975) pp. 147–167 MR0404257 Zbl 0332.14002 |
| [Ha] | R. Hartshorne, "Algebraic geometry", Springer (1977) MR0463157 Zbl 0367.14001 |
Comments
For $X$ a Noetherian scheme (or ring), let $K_n(X)$ denote the $n$-th $K$-group of (the category of) finitely-generated projective modules over $X$; cf. Algebraic K-theory. Let $\mathcal{K}$ denote the sheaf obtained by sheafifying (in the Zariski topology) the pre-sheaf $U \mapsto K_n(U)$ where $U$ runs through the open (affine) subschemes of $X$. One then has the Bloch formula [Bl]
$$\CH^p(X) \simeq H^p(X, \mathcal{K}_p)$$
providing a link between the Chow groups of $X$ and the cohomology of $X$ with values in the $\mathcal{K}$-sheaves of $X$. Using results on the algebraic K-theory of fields, [MeSu], this can be used to obtain results on Chow groups, in particular on $\CH^2$, [Co].
Cf. Sheaf theory for the notions of sheafification, pre-sheaf, sheaf, and cohomology with values in a sheaf.
References
| [Bl] | S. Bloch, "Lectures on algebraic cycles", Dept. Math. Duke Univ. (1980) MR0558224 Zbl 0436.14003 |
| [Co] | J.-L. Colliot-Thélène, "Hilbert's theorem 90 for $K_2$ with application to the Chow groups of rational surfaces" Inv. Math., 71 (1983) pp. 1–20 |
| [Fu2] | W. Fulton, "Intersection theory", Springer (1984) MR0735435 MR0732620 Zbl 0541.14005 |
| [MeSu] | A.S. Merkur'ev, A.A. Suslin, "K-cohomology of Severi–Brauer varieties and norm residue homomorphism" Math. USSR Izv., 21 (1983) pp. 307–340 Izv. Akad. Nauk SSSR Ser. Mat., 46 : 5 (1982) pp. 1011–1046 Zbl 0525.18008 Zbl 0525.18007 |
Chow ring. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Chow_ring&oldid=25197