Talk

Contact: Pieter Moree (moree@mpim-bonn.mpg.de)

Contact: Christian Kaiser (kaiser@mpim-bonn.mpg.de)

The Grothendieck ring of varieties is defined to be the free abelian group generated by varieties (over some base field $k$) modulo the relation that for a closed immersion $Y\to X$ there is a relation that $[X] = [Y] + [X \setminus Y]$. This structure can be extended to produce a space whose connected components give the Grothendieck ring of varieties and whose higher homotopy groups represent other geometric invariants of varieties. This structure is compatible with many of the structures on varieties. In particular, if the base field $k$ is finite for a variety $X$ we can consider the "almost-finite" set $X(\bar k)$, which represents the local zeta function of $X$. In this talk we will discuss how to detect interesting elements in $K_1(\text{Var})$ (which is represented by piecewise automorphisms of varieties) using this zeta function and precise point counts on $X$.

Classical Morita equivalence defines an Euler class for modules that generalizes the Euler characteristic for spaces. Using this understanding of the Euler class, fundamental structure of the class becomes accessible. Among many choices, in this talk I'll focus on compatibility of the Euler class with a familiar pairing on Hochschild homology since it also allows the exploration for different forms of duality.

In this talk I will give an overview of two related projects. The first project concerns the high-degree rational cohomology of the special linear group of a number ring $R$. Church--Farb--Putman conjectured that, when $R$ is the integers, these cohomology groups vanish in a range close to the virtual cohomological dimension. The groups $SL_n(R)$ satisfy a twisted analogue of Poincaré duality called virtual Bieri--Eckmann duality, and their rational cohomology groups are governed by $SL_n(R)$-representations called the Steinberg modules. I will discuss a recent proof of the "codimension two" case of the Church--Farb--Putman conjecture using the topology of certain simplicial complexes related to the Steinberg modules. The second project concerns Rognes’ connectivity conjecture on a family of simplicial complexes (the "common basis complexes") with implications for algebraic K-theory. I will describe work-in-progress proving Rognes' conjecture for fields, and its connections to $SL_n(R)$ and the Steinberg modules. This talk includes past and ongoing work joint with Benjamin Brück, Alexander Kupers, Jeremy Miller, Peter Patzt, Andrew Putman, and Robin Sroka.

I will discuss the theory of syntomic complexes (due to Bhatt--Morrow--Scholze and Bhatt--Lurie) and their identification for regular schemes (joint with Bhatt), inspired by some work in topological Hochschild and cyclic homology.

I will report on joint work with Achim Krause and Thomas Nikolaus on an algorithm to compute the higher algebraic $K$-groups of rings such as $\mathbb{Z}/p^n$.

This talk will introduce a notion of a stratification of a (stable presentable) category. A stratification of a scheme determines a stratification of its category of quasi-coherent sheaves. A stratification of a topological space determines a stratification of its category of linear sheaves. Such a stratification determines two reconstruction theorems, each reconstructing the category in terms of its strata and gluing data. An abelian group can be reconstructed in terms of its p-completions and its rationalization, as well as from its p-torsion and its corationalization. Concatenating these two reconstruction theorems results in a sort of duality — reflection — which is a categorification of Möbius inversion for posets. Examples of reflection are abundant, because stratifications are abundant. In algebra, reflection recovers the derived equivalences of quivers coming from BGP reflection functors. In topology, reflection is closely related to Verdier duality, which generalizes Poincaré duality. This talk will discuss all this, through many examples. This is a report on joint work with Aaron Mazel-Gee and Nick Rozenblyum.