Compactly supported $\mathbb{A}^1$-Euler characteristics of symmetric powers of cellular varieties

arXiv - MATH - K-Theory and Homology Pub Date : 2024-04-12 DOI:arxiv-2404.08486

Jesse Pajwani, Herman Rohrbach, Anna M. Viergever

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Abstract

The compactly supported $\mathbb{A}^1$-Euler characteristic, introduced by Hoyois and later refined by Levine and others, is an anologue in motivic homotopy theory of the classical Euler characteristic of complex topological manifolds. It is an invariant on the Grothendieck ring of varieties $\mathrm{K}_0(\mathrm{Var}_k)$ taking values in the Grothendieck-Witt ring $\mathrm{GW}(k)$ of the base field $k$. The former ring has a natural power structure induced by symmetric powers of varieties. In a recent preprint, Pajwani and P\'al construct a power structure on $\mathrm{GW}(k)$ and show that the compactly supported $\mathbb{A}^1$-Euler characteristic respects these two power structures for $0$-dimensional varieties, or equivalently \'etale $k$-algebras. In this paper, we define the class $\mathrm{Sym}_k$ of symmetrisable varieties to be those varieties for which the compactly supported $\mathbb{A}^1$-Euler characteristic respects the power structures and study the algebraic properties of $\mathrm{K}_0(\mathrm{Sym}_k)$. We show that it includes all cellular varieties, and even linear varieties as introduced by Totaro. Moreover, we show that it includes non-linear varieties such as elliptic curves. As an application of our main result, we compute the compactly supported $\mathbb{A}^1$-Euler characteristics of symmetric powers of Grassmannians and certain del Pezzo surfaces.

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细胞变体对称幂的紧凑支撑 $\mathbb{A}^1$-Euler 特性

紧凑支撑的$\mathbb{A}^1$-欧拉特性由霍尤瓦提出，后来由莱文等人完善，是复拓扑manifolds经典欧拉特性在动机重漫游理论中的同源物。它是在基域$k$的格罗内迪克-维特环$mathrm{GW}(k)$取值的格罗内迪克环上的一个不变量。前一个环有一个由对称幂变种诱导的天然幂结构。Pajwani 和 P\'al 在最近的预印本中构建了 $\mathrm{GW}(k)$ 上的幂结构，并证明了紧凑支持的 $\mathbb{A}^1$ 欧勒特征尊重这些 $0$ 维品种或等价于 \'etale$k$ 算法的双幂结构。本文定义了$\mathrm{Sym}_k$可对称变元类，即紧凑支撑的$\mathbb{A}^1$-欧勒特征尊重幂结构的变元，并研究了$\mathrm{K}_0(\mathrm{Sym}_k)$的代数性质。我们证明它包括了所有的单元变项，甚至包括了户太郎引入的线性变项。此外，我们还证明了它包括非线性品种，如椭圆曲线。作为我们主要结果的一个应用，我们计算了格拉斯曼对称幂和某些德尔佩佐曲面的紧凑支撑$\mathbb{A}^1$-欧拉特性。

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arXiv - MATH - K-Theory and Homology

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