scholarly journals Morita equivalence classes of $2$-blocks of defect three

2015 ◽  
Vol 144 (5) ◽  
pp. 1961-1970 ◽  
Author(s):  
Charles W. Eaton
Keyword(s):  
Morita Equivalence ◽  
Equivalence Classes

scholarly journals Classification of pointed fusion categories of dimension p3 up to weak Morita Equivalence

2020 ◽  
pp. 2140008
Author(s):  
Kevin Maya ◽  
Adriana Mejía Castaño ◽  
Bernardo Uribe
Keyword(s):  
Complete Classification ◽  
Global Dimension ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
Fusion Categories ◽  
Dimension Formula ◽  
Equivalent Categories

We give a complete classification of pointed fusion categories over [Formula: see text] of global dimension [Formula: see text] for [Formula: see text] any odd prime. We proceed to classify the equivalence classes of pointed fusion categories of dimension [Formula: see text] and we determine which of these equivalence classes have equivalent categories of modules.

Strong Morita Equivalence for Heisenberg C*-Algebras and the Positive Cones of Their K 0-Groups

1988 ◽  
Vol 40 (04) ◽  
pp. 833-864 ◽  
Author(s):  
Judith A. Packer
Keyword(s):  
Heisenberg Group ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
Crossed Products ◽  
C Algebras ◽  
Projective Representations ◽  
Discrete Heisenberg Group ◽  
Strong Morita Equivalence

In [14] we began a study of C*-algebras corresponding to projective representations of the discrete Heisenberg group, and classified these C*-algebras up to *-isomorphism. In this sequel to [14] we continue the study of these so-called Heisenberg C*-algebras, first concentrating our study on the strong Morita equivalence classes of these C*-algebras. We recall from [14] that a Heisenberg C*-algebra is said to be of class i, i ∊ {1, 2, 3}, if the range of any normalized trace on its K 0 group has rank i as a subgroup of R; results of Curto, Muhly, and Williams [7] on strong Morita equivalence for crossed products along with the methods of [21] and [14] enable us to construct certain strong Morita equivalence bimodules for Heisenberg C*-algebras.

scholarly journals Categorical Morita equivalence and monoidal Morita equivalence of semisimple Hopf algebras of dimension pqr

2019 ◽  
Vol 18 (01) ◽  
pp. 1950008
Author(s):  
Zhiqiang Yu
Keyword(s):  
Hopf Algebras ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
Dimension Formula ◽  
Morita Equivalent

In this paper, we describe the Galois objects for semisimple Hopf algebras of dimension [Formula: see text], where [Formula: see text] are distinct primes. We show that each of these Hopf algebras has only one trivial Galois object, so that they are pairwise twist inequivalent; equivalently, they are not monoidally Morita equivalent to each other. Moreover, we determine the categorical and monoidal Morita equivalence classes of these Hopf algebras.

scholarly journals Brauer groups and Galois cohomology of commutative ring spectra

2021 ◽  
Vol 157 (6) ◽  
pp. 1211-1264
Author(s):  
David Gepner ◽  
Tyler Lawson
Keyword(s):  
Fixed Point ◽  
Spectral Sequence ◽  
Commutative Ring ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
Obstruction Theory ◽  
Azumaya Algebras ◽  
Ring Spectra ◽  
K Theory ◽  
Coefficient Ring

In this paper we develop methods for classifying Baker, Richter, and Szymik's Azumaya algebras over a commutative ring spectrum, especially in the largely inaccessible case where the ring is nonconnective. We give obstruction-theoretic tools, constructing and classifying these algebras and their automorphisms with Goerss–Hopkins obstruction theory, and give descent-theoretic tools, applying Lurie's work on $\infty$ -categories to show that a finite Galois extension of rings in the sense of Rognes becomes a homotopy fixed-point equivalence on Brauer spaces. For even-periodic ring spectra $E$ , we find that the ‘algebraic’ Azumaya algebras whose coefficient ring is projective are governed by the Brauer–Wall group of $\pi _0(E)$ , recovering a result of Baker, Richter, and Szymik. This allows us to calculate many examples. For example, we find that the algebraic Azumaya algebras over Lubin–Tate spectra have either four or two Morita equivalence classes, depending on whether the prime is odd or even, that all algebraic Azumaya algebras over the complex K-theory spectrum $KU$ are Morita trivial, and that the group of the Morita classes of algebraic Azumaya algebras over the localization $KU[1/2]$ is $\mathbb {Z}/8\times \mathbb {Z}/2$ . Using our descent results and an obstruction theory spectral sequence, we also study Azumaya algebras over the real K-theory spectrum $KO$ which become Morita-trivial $KU$ -algebras. We show that there exist exactly two Morita equivalence classes of these. The nontrivial Morita equivalence class is realized by an ‘exotic’ $KO$ -algebra with the same coefficient ring as $\mathrm {End}_{KO}(KU)$ . This requires a careful analysis of what happens in the homotopy fixed-point spectral sequence for the Picard space of $KU$ , previously studied by Mathew and Stojanoska.

scholarly journals BLOCKS WITH SMALL-DIMENSIONAL BASIC ALGEBRA

2020 ◽  
pp. 1-14
Author(s):  
BENJAMIN SAMBALE
Keyword(s):  
Finite Groups ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
Basic Algebra

Abstract Linckelmann and Murphy have classified the Morita equivalence classes of p-blocks of finite groups whose basic algebra has dimension at most $12$ . We extend their classification to dimension $13$ and $14$ . As predicted by Donovan’s conjecture, we obtain only finitely many such Morita equivalence classes.

Real Af C*-Algebras With K0 of Small Rank

1989 ◽  
Vol 41 (5) ◽  
pp. 786-807
Author(s):  
T. Giordano ◽  
D. E. Handelman
Keyword(s):  
Algebraic Number ◽  
Direct Limit ◽  
Algebraic Number Field ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
C Algebras ◽  
Finite Dimensional ◽  
Real Algebra ◽  
Rank 2 ◽  
Prime 2

A real AF C*-algebra is the norm closure of a direct limit of finite dimensional real C*-algebras (with real *-algebra maps). When we use the unadorned “AF C*-algebra”, we mean the usual complex version.Let R be a simple AF C*-algebra such that K0(R) is free of rank 2 or 3. The problem is to find (up to Morita equivalence) all real AF C*-algebras A such that AꕕC≅R. This is closely related to the problem of finding all involutions on R [3], [10].For example, when the rank is 2, generically there are 8 such classes. The exceptional cases arise when the ratio of the two generators in K0(R) is a quadratic (algebraic) number, and here there are 4, 5, or 8 Morita equivalence classes, the number depending largely on the behaviour of the prime 2 in the relevant algebraic number field.

scholarly journals Shifted Poisson Structures on Differentiable Stacks

2020 ◽  
Author(s):  
Francesco Bonechi ◽  
Nicola Ciccoli ◽  
Camille Laurent-Gengoux ◽  
Ping Xu
Keyword(s):  
Differential Geometry ◽  
Morita Equivalence ◽  
Equivalence Classes ◽  
Poisson Structures ◽  
Homotopy Equivalence ◽  
Lie Groupoids ◽  
Lie Groupoid ◽  
Isomorphism Classes ◽  
Relevant Notion ◽  
Differentiable Stack

Abstract The purpose of this paper is to investigate $(+1)$-shifted Poisson structures in the context of differential geometry. The relevant notion is that of $(+1)$-shifted Poisson structures on differentiable stacks. More precisely, we develop the notion of the Morita equivalence of quasi-Poisson groupoids. Thus, isomorphism classes of $(+1)$-shifted Poisson stacks correspond to Morita equivalence classes of quasi-Poisson groupoids. In the process, we carry out the following program, which is of independent interest: (1) We introduce a ${\mathbb{Z}}$-graded Lie 2-algebra of polyvector fields on a given Lie groupoid and prove that its homotopy equivalence class is invariant under the Morita equivalence of Lie groupoids, and thus they can be considered to be polyvector fields on the corresponding differentiable stack ${\mathfrak{X}}$. It turns out that $(+1)$-shifted Poisson structures on ${\mathfrak{X}}$ correspond exactly to elements of the Maurer–Cartan moduli set of the corresponding dgla. (2) We introduce the notion of the tangent complex $T_{\mathfrak{X}}$ and the cotangent complex $L_{\mathfrak{X}}$ of a differentiable stack ${\mathfrak{X}}$ in terms of any Lie groupoid $\Gamma{\rightrightarrows } M$ representing ${\mathfrak{X}}$. They correspond to a homotopy class of 2-term homotopy $\Gamma$-modules $A[1]\rightarrow TM$ and $T^{\vee } M\rightarrow A^{\vee }[-1]$, respectively. Relying on the tools of theory of VB-groupoids including homotopy and Morita equivalence of VB-groupoids, we prove that a $(+1)$-shifted Poisson structure on a differentiable stack ${\mathfrak{X}}$ defines a morphism ${L_{\mathfrak{X}}}[1]\to{T_{\mathfrak{X}}}$.

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