# On the geometry of lattices and finiteness of Picard groups

**Authors:** Florian Eisele

arXiv: 1908.00129 · 2019-08-08

## TL;DR

This paper studies the geometric structure of lattices over orders in algebras, proving finiteness results for rigid lattices and implications for the Picard and automorphism groups of these algebraic structures.

## Contribution

It introduces the concept of rigid lattices in the context of orders and proves their finiteness, leading to new results on the finiteness of Picard groups and automorphism groups.

## Key findings

- Finitely many rigid lattices of a given dimension exist.
- Vanishing Hochschild cohomology implies finite Picard and outer automorphism groups.
- Picard groups of blocks of finite groups over f3 are always finite.

## Abstract

Let $(K,\mathcal O, k)$ be a $p$-modular system with $k$ algebraically closed and $\mathcal O$ unramified, and let $\Lambda$ be an $\mathcal O$-order in a separable $K$-algebra. We call a $\Lambda$-lattice $L$ rigid if ${\rm Ext}^1_{\Lambda}(L,L)=0$, in analogy with the definition of rigid modules over a finite-dimensional algebra. By partitioning the $\Lambda$-lattices of a given dimension into "varieties of lattices", we show that there are only finitely many rigid $\Lambda$-lattices $L$ of any given dimension. As a consequence we show that if the first Hochschild cohomology of $\Lambda$ vanishes, then the Picard group and the outer automorphism group of $\Lambda$ are finite. In particular the Picard groups of blocks of finite groups defined over $\mathcal O$ are always finite.

## Full text

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## References

20 references — full list in the complete paper: https://tomesphere.com/paper/1908.00129/full.md

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Source: https://tomesphere.com/paper/1908.00129