Lemma 62.3.1. Let $K/k$ be a field extension. Let $Z$ be an integral locally algebraic scheme over $k$. The multiplicity $m_{Z', Z_ K}$ of an irreducible component $Z' \subset Z_ K$ is $1$ or a power of the characteristic of $k$.
62.3 Cycles relative to fields
Let $k$ be a field. Let $X$ be a locally algebraic scheme over $k$. Let $r \geq 0$ be an integer. In this setting we have the group $Z_ r(X)$ of $r$-cycles on $X$, see Section 62.2.
Base change. For any field extension $k'/k$ there is a base change map $Z_ r(X) \to Z_ r(X_{k'})$, see Chow Homology, Section 42.67. Namely, given an integral closed subscheme $Z \subset X$ of dimension $r$ we send $[Z] \in Z_ r(X)$ to the $r$-cycle $[Z_{k'}]_ r \in Z_ r(X_{k'})$ associated to the closed subscheme $Z_{k'} \subset X_{k'}$ (of course in general $Z_{k'}$ is neither irreducible nor reduced). The base change map $Z_ r(X) \to Z_ r(X_{k'})$ is always injective.
Proof. If the characteristic of $k$ is zero, then $k$ is perfect and the multiplicity is always $1$ since $X_ K$ is reduced by Varieties, Lemma 33.6.4. Assume the characteristic of $k$ is $p > 0$. Let $L$ be the function field of $Z$. Since $Z$ is locally algebraic over $k$, the field extension $L/k$ is finitely generated. The ring $K \otimes _ k L$ is Noetherian (Algebra, Lemma 10.31.8). Translated into algebra, we have to show that the length of the artinian local ring $(K \otimes _ k L)_\mathfrak q$ is a power of $p$ for every minimal prime ideal $\mathfrak q$.
Let $L'/L$ be a finite purely inseparable extension, say of degree $p^ n$. Then $K \otimes _ k L \subset K \otimes _ k L'$ is a finite free ring map of degree $p^ n$ which induces a homeomorphism on spectra and purely inseparable residue field extensions. Hence for every minimal prime $\mathfrak q$ as above there is a unique minimal prime $\mathfrak q' \subset K \otimes _ k L'$ lying over it and
by Algebra, Lemma 10.52.12 applied to $M = (K \otimes _ k L')_{\mathfrak q'} \cong (K \otimes _ k L)_{\mathfrak q}^{\oplus p^ n}$. Since $[\kappa (\mathfrak q') : \kappa (\mathfrak q)]$ is a power of $p$ we conclude that it suffices to prove the statement for $L'$ and $\mathfrak q'$.
By the previous paragraph and Algebra, Lemma 10.45.3 we may assume that we have a subfield $L/k'/k$ such that $L/k'$ is separable and $k'/k$ is finite purely inseparable. Then $K \otimes _ k k'$ is an Artinian local ring. The argument of the preceding paragraph (applied to $L = k$ and $L' = k'$) shows that $\text{length}(K \otimes _ k k')$ is a power of $p$. Since $L/k'$ is the localization of a smooth $k'$-algebra (Algebra, Lemma 10.158.10). Hence $S = (K \otimes _ k L)_\mathfrak q$ is the localization of a smooth $R = K \otimes _ k k'$-algebra at a minimal prime. Thus $R \to S$ is a flat local homomorphism of Artinian local rings and $\mathfrak m_ R S = \mathfrak m_ S$. It follows from Algebra, Lemma 10.52.13 that $\text{length}(K \otimes _ k k') = \text{length}(R) = \text{length}(S) = \text{length}((K \otimes _ k L)_\mathfrak q)$ and the proof is finished. $\square$
Lemma 62.3.2. Let $k$ be a field of characteristic $p > 0$ with perfect closure $k^{perf}$. Let $X$ be an algebraic scheme over $k$. Let $r \geq 0$ be an integer. The cokernel of the injective map $Z_ r(X) \to Z_ r(X_{k^{perf}})$ is a $p$-power torsion module (More on Algebra, Definition 15.88.1).
Proof. Since $X$ is quasi-compact, the abelian group $Z_ r(X)$ is free with basis given by the integral closed subschemes of dimension $r$. Similarly for $Z_ r(X_{k^{perf}})$. Since $X_{k^{perf}} \to X$ is a homeomorphism, it follows that $Z_ r(X) \to Z_ r(X_{k^{perf}})$ is injective with torsion cokernel. Every element in the cokernel is $p$-power torsion by Lemma 62.3.1. $\square$
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