% % Do not edit the following line. The text is automatically updated by % subversion. % \svnid{$Id: 01-intro.tex 727 2024-05-06 20:00:54Z rousseau $} \selectlanguage{british} \section{The $\cC$-Albanese morphism in the presence of rational curves} \subversionInfo \begin{setting}\label{set:1} Let $X$ be a compact Kähler manifold and let $x \in X$ be any point. Assume that an Albanese of the $\cC$-pair $(X,0)$ exists. \end{setting} \begin{rem}[Mapping subvarieties to a point] Assume Setting~\ref{set:1}. If $x_1, x_2 \in X$ are any two points, it follows from the universal property of the Albanese that the varieties $\Alb_{x_1}(X,0)$ and $\Alb_{x_2}(X,0)$ are isomorphic. To be more precise, there exists a unique Lie group isomorphism $t$ that makes the following diagram commute, \[ \begin{tikzcd}[column sep=2cm] X \ar[r, "\alb_{x_1}(X{,}0)"] \ar[d, equal] & \Alb_{x_1}(X,0) \ar[d, two heads, hook, "t_{x_1x_2}"] \\ X \ar[r, "\alb_{x_2}(X{,}0)"'] & \Alb_{x_2}(X,0). \end{tikzcd} \] If $Y \subseteq X$ is any subvariety, then the following two statements are equivalent. \begin{itemize} \item The morphism $\alb_{x_1}(X,0)$ maps $Y$ to a point. \item The morphism $\alb_{x_2}(X,0)$ maps $Y$ to a point. \end{itemize} If the conditions are satisfied, then say that \emph{the Albanese morphism of $(X,0)$ maps $Y$ to a point}. \end{rem} \begin{thm}\label{thm:1}% Assume Setting~\ref{set:1}. Then, the Albanese morphism of $(X,0)$ maps all rational curves to points. \end{thm} \begin{proof} Let $C \subseteq X$ be any rational curve. The normalization of $C$ yields a diagram \[ \begin{tikzcd}[column sep=2cm] \bP¹ \ar[r, "n\text{, normalization}"'] \ar[rr, bend left=15, "\eta"] & C \ar[r, "\text{inclusion}"'] & X. \end{tikzcd} \] Consider the points $0 \in \bP¹$ and $x' := n(0) \in X$. Given that $X$ is smooth, recall from \cite{orbiAlb1} that $\eta$ is a $\cC$-morphism, between $\cC$-pairs $(\bP¹, 0)$ and $(X, 0)$. Since $\Alb_0(\bP¹,0)$ exists, the universal property of the Albanese yields a diagram \[ \begin{tikzcd}[column sep=2cm] \bP¹ \ar[r, "\alb_0(\bP¹{,}0)"] \ar[d, "n"'] & \Alb_0(\bP¹,0) \ar[d] \\ X \ar[r, "\alb_{x'}(X{,}0)"'] & \Alb_{x'}(X,0). \end{tikzcd} \] The claim follows immediately once we observe that $\Alb_0(\bP¹,0)$ is a point. \end{proof} \begin{cor}\label{cor:3}% In Setting~\ref{set:1}, assume that $X$ is rationally connected. Then, $\Alb_x(X,0)$ is a point. \end{cor} \begin{example}[Theorem~\ref{thm:1} is wrong for singular spaces] Let $\pi : S \to \bP¹$ be one of the rational ruled ``Hirzebruch'' surfaces. Let $C_S \subset S$ be any section. Construct a commutative diagram as follows, \[ \begin{tikzcd}[column sep=2cm] & S_2 \ar[r, "\alpha\text{, blow-up}"] \ar[d, "\gamma\text{, contraction}"'] & S_1 \ar[r, "\beta\text{, blow-up}"] & S \ar[r, "\pi\text{, fibre bundle}"] & \bP¹ \ar[d, equal] \\ C \ar[r, "\iota"'] & X \ar[rrr, "\rho\text{, rational fibration}"'] & & & \bP¹. \end{tikzcd} \] \begin{itemize} \item Choose four distinct points $x_1, …, x_4 \in \bP¹$. \item Choose four points $s_\bullet \in \pi^{-1}(x_\bullet) \in \bP¹$. \item Let $\beta$ be the blow-up up of the four points $s_\bullet$. \item The surface $S_1$ is smooth. The fibres $F_{1\bullet} := (\pi\circ\beta)^{-1}(x_\bullet)$ are reduced. Each fibre $F_{1\bullet}$ consists of two $(-1)$-curves, meeting transversally in a point $s_{1\bullet}$. \item Let $\alpha$ be the blow-up up of the four points $s_{1\bullet}$. \item The surface $S_2$ is smooth but the fibres $F_{2\bullet} := (\pi\circ\beta\circ\alpha)^{-1}(x_\bullet)$ are no longer reduced. Each fibre $F_{2\bullet}$ consists of two reduced $(-1)$-curves and one $(-2)$-curve $F'_{2\bullet}$ of multiplicity two. \item Let $\gamma$ be the contraction of the four points disjoint $(-2)$-curves $F'_{2\bullet}$. The map $\pi\circ\beta\circ\alpha$ factors via the contraction map because we contract fibre components only. \item Let $C \subset X$ be the strict transform of the section $C_S$. \end{itemize} The surface $X$ is then singular, with four quotient singularities of type $A_1$ over the $x_\bullet$. All fibres of $\rho$ are supported on smooth rational curves, but the fibres over $x_\bullet$ have multiplicitity two and pass through the singularities. The criterion for $\cC$-morphism spelled out in \cite{orbiAlb1} quickly implies that $\rho$ is a $\cC$-morphism between the pair $(X,0)$ and the torus quotient $(\bP¹, \frac{1}{2}·\sum_i x_i)$. The universal property of the Albanese immediately implies that the map $\rho$ factors via $\alb_x(X,0)$. A more detailed analysis, applying Theorem~\ref{thm:1} to the smooth fibres of $\rho$, shows that the torus quotient $(\bP¹, \frac{1}{2}·\sum_i x_i)$ is equal to the Albanese and that $\rho$ is the Albanese map. \end{example} \begin{itemize} \item \todo{Need example where Theorem~\ref{thm:1} fails if $X$ is singular.} \end{itemize} \begin{cor}\label{cor:2} Let $X$ be a projective manifold and let $x \in X$ be any point. Let $\mu : X \to Y$ be a morphism to a normal projective variety. If all fibres of $\mu$ are rationally chain connected, then $\alb_x(X,0)$ factors via $\mu$, \[ \begin{tikzcd} X \ar[r, "\mu"'] \ar[rr, bend left=15, "\alb_x(X{,}0)"] & Y \ar[r, "\exists!\:\beta"'] & \Alb_x(X,0). \end{tikzcd} \] \end{cor} \begin{rem} --- \begin{itemize} \item Corollary~\ref{cor:2} does not equip $Y$ with the structure of a $\cC$-pair. \item Corollary~\ref{cor:2} does not assume that $\mu$ is a morphism of $\cC$-pairs. \item Even if $\mu$ is a morphism of $\cC$-pairs, Corollary~\ref{cor:2} does not claim that $\beta$ is a morphism of $\cC$-pairs. \item Corollary~\ref{cor:2} neither gives a morphism between $\Alb_x(X,0)$ and $\Alb_{\mu(x)}(Y,0)$ nor does it claim that these are isomorphic. \end{itemize} \end{rem} \begin{itemize} \item \todo{Kummer K3s are nice examples where the Albanese grows when we contract rational curves.} \item \todo{Want more examples to showcase all the things that can go wrong.} \item \todo{Corollary~\ref{cor:2} implies that the $\cC$-Albanese map factors via the MRC fibration of $X$, and via any map from $X$ to one of its minimal models. This should be exploitable in geometrically meaningful situations.} \end{itemize} \todo{There are settings where the factorization of Corollary~\ref{cor:2} is a factorization into morphisms of $\cC$-pairs.} \begin{thm} Birational projective manifolds $X$ and $Y$ have canonically isomorphic $\cC$-Albanese varieties. \end{thm} \begin{proof} \todo{PENDING} \end{proof} \begin{thm} Let $X$ be a projective manifold and let $x \in X$ be any point. Let $\mu : X \to Y$ be an MRC fibration of $X$, where $Y$ is again a projective manifold. Then, the $\cC$-pairs $\Alb_x(X,0)$ and $\Alb_{\mu(x)}(Y,0)$ are naturally isomorphic. \end{thm} \begin{proof} \todo{PENDING} \end{proof} \section{Examples} \begin{itemize} \item \todo{Discuss the Stoppino-example: general type, simply-connected, augmented irregularity zero, but has a non-trivial $\cC$-Albanse.} \end{itemize} \section{The $\cC$-Albanese morphism for special manifolds} \begin{itemize} \item \todo{Discuss special surfaces.} \item \todo{Figure out what we can say for special threefolds.} \end{itemize} % !TEX root = orbiAlb1