Base change in crystalline cohomology?

Question

Does one have a base change theorem in crystalline cohomology like in étale cohomology?

Suppose one has the following cartesian diagram

$$ \newcommand{\ra}[1]{\!\!\!\!\!\!\!\xrightarrow{\quad#1\quad}\!\!\!\!\!\!\!\!} \newcommand{\da}[1]{\left\downarrow{\scriptstyle#1}\vphantom{\displaystyle\int_0^1}\right.} % \begin{array}{lll} U & \to & V \\ \da{f} & & \da{g} \\ X & \ra{h} & Y \\ \end{array} $$

Where $U,V, X, Y$ are all smooth proper scheme over $\mathbb{Z}_p$ and $h$ is embedding. Assume $g$ is a good enough map (smooth, proper, etc..). Consier the map $$ h^* R^1(g_*)_{cry}(\mathcal{O}_{V})\to R^1 (f_{*})_{cry}(\mathcal{O}_U) $$ Is the above map an isomorphism (but not in the sense of derived categories)?

Answer 1

You finish your question by insisting that the isomorphism be such but "not in the sense of derived categories", which I do not understand completely, since both objects you have at hands naturally live in a derived category. If you are happy with that, Corollary 7.12 of Berthelot&Ogus' "Notes on Crystalline Cohomology" says that if you assume that

• $g$ is quasi-separated and smooth;
• $Y$ is quasi-compact; and, most important
• $U=X\times_Y V$,

then indeed $$ \mathbb{L}h_\mathrm{cris}^*\mathbb{R}g_{\mathrm{cris}*}\mathcal{O}_V\to \mathbb{R}f_{\mathrm{cris}*}\mathcal{O}_U $$ is an isomorphism in the derived category of crystals on $X$ (a priori both terms live in the derived category of $\mathcal{O}_{X/\mathbb{Z}_p}$-modules, but Corollary 7.11 tells you that they are actually in the derived category of crystals under the above assumptions).