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Main Author: Maakestad, Helge Øystein
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.22314
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author Maakestad, Helge Øystein
author_facet Maakestad, Helge Øystein
contents In the paper I introduce a new characteristic class $c(E)$ for a finite rank vector bundle $E$ on an affine scheme $S:=Spec(A)$ - the fundamental class of $E$. The class $c(E)$ is not a characteristic class in the classical sense in the sense that it lives in a pointed cohomology torsor $\operatorname{Ext}^1(L, \operatorname{End}_A(E))$. Most characteristic classes lives in a cohomology group. The pointed cohomology torsor $\operatorname{Ext}^1(L, \operatorname{End}_A(E))$ is a torsor on the abelian group $\operatorname{H}^2(L, Z(\operatorname{End}_A(E)))$ where $Z(\operatorname{End}_A(E))$ is the center of the ring of endomorphisms of $E$ and where the cohomology is the Lie-Rinehart cohomology of the center. The class $c(E)$ is trivial if and only if $E$ has a flat algebraic connection. Hence the class $c(T_S)$ where $T_S$ is the tangent bundle, is an an obstruction for $S$ to be algebraically parallelizable. I use a connection $\nabla$ to define $c(E)$ and I also prove the class $c(E)$ is independent of choice of connection, hence $c(E)$ is an invariant of the vector bundle $E$. The class generalize the Chern class, the Pontryagin class, the Euler class and the Teleman characteristic class. I prove using an explicit example that the class $c(E)$ is stronger than the Chern class and the Euler class. I also give a new proof of a formula for the curvature of a connection $\nabla$ in terms of an idempotent endomorphism $ϕ$ defining $E$. This formula was claimed and proved in a paper put out on the arXiv in 2011, and in this paper I give a new proof that is easier to read. The class may be interesting in the study of the "cancellation problem" in affine algebraic geometry and the problem of giving algebraic formulas for the topological Euler characteristic. I also calculate the algebraic deRham cohomology of the complex two sphere and prove it is infinite dimensional.
format Preprint
id arxiv_https___arxiv_org_abs_2503_22314
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A universal characteristic class for vector bundles with a connection
Maakestad, Helge Øystein
Algebraic Geometry
Commutative Algebra
Algebraic Topology
Differential Geometry
16S30, 17B45, 17B56, 17B35, 20G10, 20G05
In the paper I introduce a new characteristic class $c(E)$ for a finite rank vector bundle $E$ on an affine scheme $S:=Spec(A)$ - the fundamental class of $E$. The class $c(E)$ is not a characteristic class in the classical sense in the sense that it lives in a pointed cohomology torsor $\operatorname{Ext}^1(L, \operatorname{End}_A(E))$. Most characteristic classes lives in a cohomology group. The pointed cohomology torsor $\operatorname{Ext}^1(L, \operatorname{End}_A(E))$ is a torsor on the abelian group $\operatorname{H}^2(L, Z(\operatorname{End}_A(E)))$ where $Z(\operatorname{End}_A(E))$ is the center of the ring of endomorphisms of $E$ and where the cohomology is the Lie-Rinehart cohomology of the center. The class $c(E)$ is trivial if and only if $E$ has a flat algebraic connection. Hence the class $c(T_S)$ where $T_S$ is the tangent bundle, is an an obstruction for $S$ to be algebraically parallelizable. I use a connection $\nabla$ to define $c(E)$ and I also prove the class $c(E)$ is independent of choice of connection, hence $c(E)$ is an invariant of the vector bundle $E$. The class generalize the Chern class, the Pontryagin class, the Euler class and the Teleman characteristic class. I prove using an explicit example that the class $c(E)$ is stronger than the Chern class and the Euler class. I also give a new proof of a formula for the curvature of a connection $\nabla$ in terms of an idempotent endomorphism $ϕ$ defining $E$. This formula was claimed and proved in a paper put out on the arXiv in 2011, and in this paper I give a new proof that is easier to read. The class may be interesting in the study of the "cancellation problem" in affine algebraic geometry and the problem of giving algebraic formulas for the topological Euler characteristic. I also calculate the algebraic deRham cohomology of the complex two sphere and prove it is infinite dimensional.
title A universal characteristic class for vector bundles with a connection
topic Algebraic Geometry
Commutative Algebra
Algebraic Topology
Differential Geometry
16S30, 17B45, 17B56, 17B35, 20G10, 20G05
url https://arxiv.org/abs/2503.22314