Bloch's higher Chow group

Last updated October 21, 2023

In algebraic geometry, Bloch's higher Chow groups, a generalization of Chow group, is a precursor and a basic example of motivic cohomology (for smooth varieties). It was introduced by Spencer Bloch ( Bloch 1986 ) and the basic theory has been developed by Bloch and Marc Levine.

Motivation

One of the motivations for higher Chow groups comes from homotopy theory. In particular, if $\alpha ,\beta \in Z_{*}(X)$ are algebraic cycles in $X$ which are rationally equivalent via a cycle $\gamma \in Z_{*}(X\times \Delta ^{1})$ , then $\gamma$ can be thought of as a path between $\alpha$ and $\beta$ , and the higher Chow groups are meant to encode the information of higher homotopy coherence. For example,

${\text{CH}}^{*}(X,0)$

can be thought of as the homotopy classes of cycles while

${\text{CH}}^{*}(X,1)$

can be thought of as the homotopy classes of homotopies of cycles.

Definition

Let X be a quasi-projective algebraic scheme over a field (“algebraic” means separated and of finite type).

For each integer $q\geq 0$ , define

\Delta ^{q}=\operatorname {Spec} (\mathbb {Z} [t_{0},\dots ,t_{q}]/(t_{0}+\dots +t_{q}-1)),

which is an algebraic analog of a standard q-simplex. For each sequence $0\leq i_{1}<i_{2}<\cdots <i_{r}\leq q$ , the closed subscheme $t_{i_{1}}=t_{i_{2}}=\cdots =t_{i_{r}}=0$ , which is isomorphic to $\Delta ^{q-r}$ , is called a face of $\Delta ^{q}$ .

For each i, there is the embedding

\partial _{q,i}:\Delta ^{q-1}{\overset {\sim }{\to }}\{t_{i}=0\}\subset \Delta ^{q}.

We write $Z_{i}(X)$ for the group of algebraic i-cycles on X and $z_{r}(X,q)\subset Z_{r+q}(X\times \Delta ^{q})$ for the subgroup generated by closed subvarieties that intersect properly with $X\times F$ for each face F of $\Delta ^{q}$ .

Since $\partial _{X,q,i}=\operatorname {id} _{X}\times \partial _{q,i}:X\times \Delta ^{q-1}\hookrightarrow X\times \Delta ^{q}$ is an effective Cartier divisor, there is the Gysin homomorphism:

\partial _{X,q,i}^{*}:z_{r}(X,q)\to z_{r}(X,q-1)

,

that (by definition) maps a subvariety V to the intersection $(X\times \{t_{i}=0\})\cap V.$

Define the boundary operator $d_{q}=\sum _{i=0}^{q}(-1)^{i}\partial _{X,q,i}^{*}$ which yields the chain complex

\cdots \to z_{r}(X,q){\overset {d_{q}}{\to }}z_{r}(X,q-1){\overset {d_{q-1}}{\to }}\cdots {\overset {d_{1}}{\to }}z_{r}(X,0).

Finally, the q-th higher Chow group of X is defined as the q-th homology of the above complex:

\operatorname {CH} _{r}(X,q):=\operatorname {H} _{q}(z_{r}(X,\cdot )).

(More simply, since $z_{r}(X,\cdot )$ is naturally a simplicial abelian group, in view of the Dold–Kan correspondence, higher Chow groups can also be defined as homotopy groups $\operatorname {CH} _{r}(X,q):=\pi _{q}z_{r}(X,\cdot )$ .)

For example, if $V\subset X\times \Delta ^{1}$ ^[2] is a closed subvariety such that the intersections $V(0),V(\infty )$ with the faces $0,\infty$ are proper, then $d_{1}(V)=V(0)-V(\infty )$ and this means, by Proposition 1.6. in Fulton’s intersection theory, that the image of $d_{1}$ is precisely the group of cycles rationally equivalent to zero; that is,

\operatorname {CH} _{r}(X,0)=

the r-th Chow group of X.

Properties

Functoriality

Proper maps $f:X\to Y$ are covariant between the higher chow groups while flat maps are contravariant. Also, whenever $Y$ is smooth, any map to $Y$ is contravariant.

Homotopy invariance

If $E\to X$ is an algebraic vector bundle, then there is the homotopy equivalence

${\text{CH}}^{*}(X,n)\cong {\text{CH}}^{*}(E,n)$

Localization

Given a closed equidimensional subscheme $Y\subset X$ there is a localization long exact sequence

${\begin{aligned}\cdots \\{\text{CH}}^{*-d}(Y,2)\to {\text{CH}}^{*}(X,2)\to {\text{CH}}^{*}(U,2)\to &\\{\text{CH}}^{*-d}(Y,1)\to {\text{CH}}^{*}(X,1)\to {\text{CH}}^{*}(U,1)\to &\\{\text{CH}}^{*-d}(Y,0)\to {\text{CH}}^{*}(X,0)\to {\text{CH}}^{*}(U,0)\to &{\text{ }}0\end{aligned}}$

where $U=X-Y$ . In particular, this shows the higher chow groups naturally extend the exact sequence of chow groups.

Localization theorem

( Bloch 1994 ) showed that, given an open subset $U\subset X$ , for $Y=X-U$ ,

z(X,\cdot )/z(Y,\cdot )\to z(U,\cdot )

is a homotopy equivalence. In particular, if $Y$ has pure codimension, then it yields the long exact sequence for higher Chow groups (called the localization sequence).

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References

↑ Lecture Notes on Motivic Cohomology (PDF). Clay Math Monographs. p. 159.
↑ Here, we identify $\Delta ^{1}$ with a subscheme of $\mathbb {P} ^{1}$ and then, without loss of generality, assume one vertex is the origin 0 and the other is ∞.

Bloch, Spencer (September 1986). "Algebraic cycles and higher K-theory". Advances in Mathematics . 61: 267–304. doi: 10.1016/0001-8708(86)90081-2 .
Bloch, Spencer (1994). "The moving lemma for higher Chow groups". Journal of Algebraic Geometry. 3: 537–568.
Peter Haine, An Overview of Motivic Cohomology
Vladmir Voevodsky, “Motivic cohomology groups are isomorphic to higher Chow groups in any characteristic,” International Mathematics Research Notices 7 (2002), 351–355.

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[1] Lecture Notes on Motivic Cohomology (PDF). Clay Math Monographs. p. 159.

[2] Here, we identify $\Delta ^{1}$ with a subscheme of $\mathbb {P} ^{1}$ and then, without loss of generality, assume one vertex is the origin 0 and the other is ∞.

[1]

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