Reference request on birational invariance of Chow group of zero cycles of degree zero

A reference for birational equivalence of $CH_0$ is Fulton's Intersection Theory [1], Example 16.1.11. In the example, he makes the assumption that $k$ is algebraically closed, but he never uses it. Since the argument is fairly short, let me repeat it here.

Theorem. Let $k$ be a field, and let $X$ and $Y$ be smooth proper $k$-varieties. If $X$ and $Y$ are birational, then $CH_0(X) \cong CH_0(Y)$.

Proof. Let $f \colon X \dashrightarrow Y$ be a birational map. Let $\Gamma \subseteq X \times Y$ be the closure of the graph. Then $\Gamma$ defines maps \begin{align*} f_* \colon CH_0(X) &\to CH_0(Y) & f^* \colon CH_0(Y) &\to CH_0(X)\\ a &\mapsto \pi_{Y,*}(\Gamma \cdot \pi_X^* a), & b &\mapsto \pi_{X,*}(\Gamma \cdot \pi_Y^* b). \end{align*} The composition $f^* \circ f_*$ (resp. $f_* \circ f^*$) is given by the cycle $\Gamma^\top \circ \Gamma := \pi_{13, *} (\pi_{12}^* \Gamma \cdot \pi_{23}^* \Gamma^\top)$ on $X \times X$ (resp. by $\Gamma \circ \Gamma^\top$ on $Y \times Y$); see [loc. cit., Def. 16.1.1 and Prop. 16.1.2(a)] for details.

Let $V \subseteq Y$ be an open such that $f$ induces an isomorphism $f^{-1}(V) \stackrel\sim\to V$. Let $U = f^{-1}(V)$, $Z = X \setminus U$, and $W = Y \setminus V$. I claim that the cycle $\varepsilon := \Gamma^\top \circ \Gamma - \Delta_X$ is supported on $Z \times Z$. By the short exact sequence of [loc. cit., Prop. 1.8], it suffices to show that the restriction of $\varepsilon$ to $S := X \times X \setminus Z \times Z = X \times U \cup U \times X$ is zero. Let $$T := (X \times Y \times U) \cup (U \times Y \times X) = \pi_{13}^{-1} (S).$$ Then the restriction of $\varepsilon$ to $S$ is the pushforward along $\pi_{13}$ of $$\left.\left(\pi_{12}^* \Gamma \cdot \pi_{23}^* \Gamma^\top\right)\right|_T.\tag{1}$$ We can compute the latter as $$\left.\left(\pi_{12}^* \Gamma\right)\right|_T \cdot \left.\left(\pi_{23}^* \Gamma^\top\right)\right|_T.$$ This is a proper intersection, and the intersection is equal to the 'diagonal' $$\left\{(a,b,c) \in U \times V \times U\ \big|\ f(a)=b=f(c)\right\}.$$ Indeed, the intersection agrees with this set on both $X \times Y \times U$ and $U \times Y \times X$.

Then the pushforward of (1) is $\Delta_U$. Hence $\varepsilon$ vanishes on $S$, so it is supported on $Z \times Z$. In particular, the projections $\pi_{1,*} \varepsilon, \pi_{2,*} \varepsilon \in CH_*(X)$ are supported on $Z$.

The punchline is that $\varepsilon$ acts as the identity on $CH_0(X)$ by the moving lemma. Indeed, any $0$-cycle $a$ on a smooth variety can be moved away from $Z$, so the intersection $\pi_1^* a \cdot \varepsilon$ is zero.

This proves that $f^* \circ f_*$ is the identity, and by symmetry the same holds for $f_* \circ f^*$. $\square$

Remark. It is even true that $CH_0$ is a stable birational invariant: if $X$ and $Y$ are smooth and proper varieties with $X \times \mathbb P^n \stackrel\sim\dashrightarrow Y \times \mathbb P^m$, then $CH_0(X) \cong CH_0(Y)$. (The only thing left to prove is that $CH_0(X) \cong CH_0(X \times \mathbb P^1)$, since we already know the result for birational varieties.)

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Remark. The reason Fulton only proves the theorem for algebraically closed fields is that Fulton only proves the moving lemma over those fields. For a proof of the moving lemma over arbitrary fields, see Roberts's appendix to the Oslo 1970 Algebraic Geometry proceedings [2] (finite fields are addressed separately).

References:

[1] Fulton, William. Intersection theory (second edition). Ergebnisse der Mathematik und ihrer Grenzgebiete. 3. Folge. Springer-Verlag, Berlin, 1998. ISBN: 3-540-62046-X; 0-387-98549-2. MR1644323

[2] Roberts, Joel. Chow's moving lemma. Appendix 2 to: "Motives" by Steven L. Kleiman. Algebraic geometry, Oslo 1970 (Proc. Fifth Nordic Summer School in Math.), pp. 89--96. Wolters-Noordhoff, Groningen, 1972. MR0382269

Using Jason Starr's comment I was able (I think) to figure out the case of $\pi_1(X)^0$. For anyone who stumbles across this with the same question in mind I add a sketch of the proof in an answer. For the experts, if you feel like leaving a comment whether my reasoning is correct, that would be great.

Let $\phi: X \rightarrow Y$ be a rational map, i.e. defined on some open $U \subset X$. Because $X$ is normal, $Z := X \backslash U$ has codimension at least two. This means the dimenson of the ring $\mathcal{O}_{X,z}$ is at least two for each point $z \in Z$. But then this local ring is pure (SGA 2, Exp. X, Thm 3.4), which in turn implies the couple $(X,Z)$ is pure (SGA 2, Exp. X, prop. 3.3), so that the categories $\operatorname{FEt}(X)$ and $\operatorname{FEt}(U)$ are equivalent.

Since $X$ and $Y$ are birational, we can find an open $V \subset Y$ such that $U$ is isomorphic to $V$ and in the same way we show $V$ and $Y$ have the same \'etale coverings. This shows $\pi_1(X) = \pi_1(U) = \pi_1(V) = \pi_1(Y)$ as desired, which proves in particular what I wanted to show.