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Hauptverfasser: Fernández, David, Herscovich, Estanislao
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2501.17764
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author Fernández, David
Herscovich, Estanislao
author_facet Fernández, David
Herscovich, Estanislao
contents In this article, we explore the following statement made by V. Ginzburg and T. Schedler in [Selecta Math. (N.S.) 16 (2010), no. 4, 673-730]: "an adequate framework for doing noncommutative differential geometry is provided by the notion of wheelspace. Wheelspaces form a symmetric monoidal category". However, the category of wheelspaces turns out not to be monoidal. To address this, we introduce generalized wheelspaces, which do form a symmetric monoidal category and provide solid ground for the theory of wheelgebras. To support their first claim, Ginzburg and Schedler defined Poisson (Fock) wheelgebras in connection with Van den Bergh's double Poisson algebras via the Fock functor. We provide strong evidence to their claim by introducing symplectic wheelgebras and prove that the Fock functor sends smooth bisymplectic algebras, as defined by W. Crawley-Boevey, V. Ginzburg and P. Etingof, into our symplectic wheelgebras. In the process, we develop a Cartan calculus adapted to this wheeled context. Moreover, we present a wheeled version of the significant Van den Bergh functor, which facilitates a formalization of the Kontsevich-Rosenberg principle, bridging the noncommutative and commutative frameworks. After establishing that the classical Van den Bergh functor factors through our wheeled version, we show that symplectic Fock wheelgebras naturally induce symplectic algebras on representation schemes.
format Preprint
id arxiv_https___arxiv_org_abs_2501_17764
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Symplectic wheelgebras and noncommutative geometry
Fernández, David
Herscovich, Estanislao
Quantum Algebra
Algebraic Geometry
Rings and Algebras
Symplectic Geometry
16W99, 14A22
In this article, we explore the following statement made by V. Ginzburg and T. Schedler in [Selecta Math. (N.S.) 16 (2010), no. 4, 673-730]: "an adequate framework for doing noncommutative differential geometry is provided by the notion of wheelspace. Wheelspaces form a symmetric monoidal category". However, the category of wheelspaces turns out not to be monoidal. To address this, we introduce generalized wheelspaces, which do form a symmetric monoidal category and provide solid ground for the theory of wheelgebras. To support their first claim, Ginzburg and Schedler defined Poisson (Fock) wheelgebras in connection with Van den Bergh's double Poisson algebras via the Fock functor. We provide strong evidence to their claim by introducing symplectic wheelgebras and prove that the Fock functor sends smooth bisymplectic algebras, as defined by W. Crawley-Boevey, V. Ginzburg and P. Etingof, into our symplectic wheelgebras. In the process, we develop a Cartan calculus adapted to this wheeled context. Moreover, we present a wheeled version of the significant Van den Bergh functor, which facilitates a formalization of the Kontsevich-Rosenberg principle, bridging the noncommutative and commutative frameworks. After establishing that the classical Van den Bergh functor factors through our wheeled version, we show that symplectic Fock wheelgebras naturally induce symplectic algebras on representation schemes.
title Symplectic wheelgebras and noncommutative geometry
topic Quantum Algebra
Algebraic Geometry
Rings and Algebras
Symplectic Geometry
16W99, 14A22
url https://arxiv.org/abs/2501.17764