Search results for "Mathematics - K-Theory and Homology"

showing 7 items of 7 documents

Commuting powers and exterior degree of finite groups

2011

In [P. Niroomand, R. Rezaei, On the exterior degree of finite groups, Comm. Algebra 39 (2011), 335-343] it is introduced a group invariant, related to the number of elements $x$ and $y$ of a finite group $G$, such that $x \wedge y = 1_{G \wedge G}$ in the exterior square $G \wedge G$ of $G$. This number gives restrictions on the Schur multiplier of $G$ and, consequently, large classes of groups can be described. In the present paper we generalize the previous investigations on the topic, focusing on the number of elements of the form $h^m \wedge k$ of $H \wedge K$ such that $h^m \wedge k = 1_{H \wedge K}$, where $m \ge 1$ and $H$ and $K$ are arbitrary subgroups of $G$.

Combinatorics20J99 20D15 20D60 20C25General MathematicsMathematics - K-Theory and HomologyFOS: MathematicsHomological algebraK-Theory and Homology (math.KT)Invariant (mathematics)Exterior algebraMathematicsSchur multiplier
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Towards Vorst's conjecture in positive characteristic

2018

Vorst's conjecture relates the regularity of a ring with the $\mathbb{A}^1$-homotopy invariance of its $K$-theory. We show a variant of this conjecture in positive characteristic.

CombinatoricsMathematics - Algebraic GeometryRing (mathematics)Algebra and Number TheoryConjectureMathematics::K-Theory and HomologyMathematics - K-Theory and HomologyFOS: MathematicsK-Theory and Homology (math.KT)Algebraic Geometry (math.AG)Valuation ringMathematicsCompositio Mathematica
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About Leibniz cohomology and deformations of Lie algebras

2011

We compare the second adjoint and trivial Leibniz cohomology spaces of a Lie algebra to the usual ones by a very elementary approach. The comparison gives some conditions, which are easy to verify for a given Lie algebra, for deciding whether it has more Leibniz deformations than just the Lie ones. We also give the complete description of a Leibniz (and Lie) versal deformation of the 4-dimensional diamond Lie algebra, and study the case of its 5-dimensional analogue.

Leibniz algebraPure mathematicsAlgebra and Number TheoryMathematics::Rings and AlgebrasInfinitesimal deformationK-Theory and Homology (math.KT)17A32 17B56 14D15CohomologyMathematics::K-Theory and HomologyLie algebraMathematics - Quantum AlgebraMathematics - K-Theory and HomologyFOS: MathematicsQuantum Algebra (math.QA)Mathematics
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Geometric models for algebraic suspensions

2021

We analyze the question of which motivic homotopy types admit smooth schemes as representatives. We show that given a pointed smooth affine scheme $X$ and an embedding into affine space, the affine deformation space of the embedding gives a model for the ${\mathbb P}^1$ suspension of $X$; we also analyze a host of variations on this observation. Our approach yields many examples of ${\mathbb A}^1$-$(n-1)$-connected smooth affine $2n$-folds and strictly quasi-affine ${\mathbb A}^1$-contractible smooth schemes.

Mathematics - Algebraic GeometryMathematics - Geometric Topology14F42 14D06 55P40General MathematicsMathematics - K-Theory and HomologyFOS: Mathematics[MATH.MATH-AG] Mathematics [math]/Algebraic Geometry [math.AG]Algebraic Topology (math.AT)Geometric Topology (math.GT)K-Theory and Homology (math.KT)[MATH.MATH-AG]Mathematics [math]/Algebraic Geometry [math.AG]Mathematics - Algebraic TopologyAlgebraic Geometry (math.AG)
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Some considerations on the nonabelian tensor square of crystallographic groups

2011

The nonabelian tensor square $G\otimes G$ of a polycyclic group $G$ is a polycyclic group and its structure arouses interest in many contexts. The same assertion is still true for wider classes of solvable groups. This motivated us to work on two levels in the present paper: on a hand, we investigate the growth of the Hirsch length of $G\otimes G$ by looking at that of $G$, on another hand, we study the nonabelian tensor product of pro--$p$--groups of finite coclass, which are a remarkable class of solvable groups without center, and then we do considerations on their Hirsch length. Among other results, restrictions on the Schur multiplier will be discussed.

Pure mathematicsGeneral MathematicsStructure (category theory)K-Theory and Homology (math.KT)Center (group theory)Group Theory (math.GR)Square (algebra)Tensor productSolvable group20F05 20F45 20F99 20J99Tensor (intrinsic definition)Mathematics - K-Theory and HomologyFOS: MathematicsPolycyclic groupMathematics - Group TheoryMathematicsSchur multiplier
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The homotopy Leray spectral sequence

2018

In this work, we build a spectral sequence in motivic homotopy that is analogous to both the Serre spectral sequence in algebraic topology and the Leray spectral sequence in algebraic geometry. Here, we focus on laying the foundations necessary to build the spectral sequence and give a convenient description of its $E_2$-page. Our description of the $E_2$-page is in terms of homology of the local system of fibers, which is given using a theory similar to Rost's cycle modules. We close by providing some sample applications of the spectral sequence and some hints at future work.

Serre spectral sequencePure mathematicsHomotopy[MATH.MATH-AG] Mathematics [math]/Algebraic Geometry [math.AG]K-Theory and Homology (math.KT)Leray spectral sequenceAlgebraic geometryHomology (mathematics)Mathematics::Algebraic TopologyMathematics - Algebraic GeometryLocal systemMathematics::K-Theory and HomologySpectral sequenceMathematics - K-Theory and HomologyFOS: MathematicsMSC 14F42 (14-06)Algebraic Topology (math.AT)Mathematics - Algebraic Topology14F42 55R20 19E15[MATH.MATH-AG]Mathematics [math]/Algebraic Geometry [math.AG]Algebraic Geometry (math.AG)Mathematics
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THE HOMOLOGY OF DIGRAPHS AS A GENERALIZATION OF HOCHSCHILD HOMOLOGY

2010

J. Przytycki has established a connection between the Hochschild homology of an algebra $A$ and the chromatic graph homology of a polygon graph with coefficients in $A$. In general the chromatic graph homology is not defined in the case where the coefficient ring is a non-commutative algebra. In this paper we define a new homology theory for directed graphs which takes coefficients in an arbitrary $A-A$ bimodule, for $A$ possibly non-commutative, which on polygons agrees with Hochschild homology through a range of dimensions.

[ MATH.MATH-GT ] Mathematics [math]/Geometric Topology [math.GT]57M15 16E40 05C20Homology (mathematics)[ MATH.MATH-CO ] Mathematics [math]/Combinatorics [math.CO]Mathematics::Algebraic Topology01 natural sciencesCombinatoricsMathematics - Geometric TopologyMathematics::K-Theory and Homology[MATH.MATH-GT]Mathematics [math]/Geometric Topology [math.GT][MATH.MATH-CO]Mathematics [math]/Combinatorics [math.CO][ MATH.MATH-KT ] Mathematics [math]/K-Theory and Homology [math.KT]0103 physical sciencesFOS: MathematicsMathematics - CombinatoricsChromatic scale0101 mathematicsMathematics::Symplectic GeometryMathematicsAlgebra and Number TheoryHochschild homologyApplied Mathematics010102 general mathematicsGeometric Topology (math.GT)K-Theory and Homology (math.KT)Directed graphMathematics::Geometric TopologyGraphMathematics - K-Theory and HomologyPolygon[MATH.MATH-KT]Mathematics [math]/K-Theory and Homology [math.KT]BimoduleCombinatorics (math.CO)010307 mathematical physicsJournal of Algebra and Its Applications
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