Finiteness of the Brauer group for flat proper schemes over $\operatorname{Spec} \mathbf{Z}$

Question

One fundamental conjecture on the Brauer group is that $\operatorname{Br}(X)$ is finite for $X/\operatorname{Spec} \mathbf{Z}$ proper. By class field theory (the theorem of Albert–Brauer–Hasse–Noether), this is true for $\dim{X} = 1$. For varieties $X$ over finite fields, the finiteness of $\operatorname{Br}(X)[\ell^\infty]$ is equivalent to the surjectivity of the cycle class map $\operatorname{Pic}(X) \otimes \mathbf{Z}_\ell \to \operatorname{H}^2(X,\mathrm{Z}_\ell(1))$ (the Tate conjecture in dimension $1$). The Tate conjecture in dimension $1$ over finite fields is known for smooth projective curves (trivial), Abelian varieties (Tate) and K3 surfaces (at least for characteristic $> 3$), and hence for products of such varieties.

Are there results on the finiteness (of an $\ell$-primary part) of the Brauer group of schemes flat and proper over $\operatorname{Spec} \mathbf{Z}$ of dimension $> 1$?

Answer 1

Let $\mathscr{C}/X$ be a relative curve with a section, e.g. a relative elliptic curve. Then there is a short exact sequence $$0 \to \mathrm{Br}(X) \to \mathrm{Br}(\mathscr{C}) \to Ш(\mathbf{Pic}^0_{\mathscr{C}/X}/X) \to 0$$ (see https://www.timokeller.name/TateShafarevich.pdf, Theorem 4.27; for $\dim{X}=1$, this is a theorem of Grothendieck).

So let $X$ be the spectrum of the ring of integers of a number field and $\mathscr{C}/X$ a relative elliptic curve with finite Ш.

Answer 2

Not sure this is too interesting, but I however think that the case when $X \rightarrow \text{Spec}(\mathbb{Z})$ is proper and smooth(!) should follow from a result proven independently by Fontaine and Abrashkin that implies that the Hodge-numbers are zero for $i+j \leq 3$ and $i \neq j$.