From Brauer graph algebras to biserial weighted surface algebras
Karin Erdmann, Andrzej Skowro\'nski

TL;DR
This paper establishes a deep connection between Brauer graph algebras and biserial weighted surface algebras, showing they are essentially the same class under certain algebraic constructions related to triangulated surfaces.
Contribution
It proves that Brauer graph algebras are exactly the indecomposable idempotent algebras of biserial weighted surface algebras and also relate them to periodic weighted surface algebras.
Findings
Brauer graph algebras coincide with indecomposable idempotent algebras of biserial weighted surface algebras
Brauer graph algebras are idempotent algebras of periodic weighted surface algebras
Connection between algebraic structures and triangulated surfaces established
Abstract
We prove that the class of Brauer graph algebras coincides with the class of indecomposable idempotent algebras of biserial weighted surface algebras. These algebras are associated to triangulated surfaces with arbitrarily oriented triangles, investigated in [17] and [18]. Moreover we prove that Brauer graph algebras are idempotent algebras of periodic weighted surface algebras, investigated in [17] and [19].
Peer Reviews
No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.
Videos
No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.
††The authors gratefully acknowledge support from the research grant DEC-2011/02/A/ST1/00216 of the National Science Center Poland.
From Brauer graph algebras to biserial weighted surface algebras
Karin Erdmann
Mathematical Institute, Oxford University, ROQ, Oxford OX2 6GG, United Kingdom
and
Andrzej Skowroński
Faculty of Mathematics and Computer Science, Nicolaus Copernicus University, Chopina 12/18, 87-100 Toruń, Poland
Abstract.
We prove that the class of Brauer graph algebras coincides with the class of indecomposable idempotent algebras of biserial weighted surface algebras. These algebras are associated to triangulated surfaces with arbitrarily oriented triangles, investigated recently in [17] and [18]. Moreover, we prove that Brauer graph algebras are idempotent algebras of periodic weighted surface algebras, investigated in [17] and [19].
Keywords: Brauer graph algebra, Weighted surface algebra, Biserial weighted surface algebra, Symmetric algebra, Special biserial algebra, Tame algebra, Periodic algebra, Quiver combinatorics
2010 MSC: 05E99, 16G20, 16G70, 20C20
2010 Mathematics Subject Classification:
05E99, 16G20, 16G70, 20C20
1. Introduction and the main results
Throughout this paper, will denote a fixed algebraically closed field. By an algebra we mean an associative, finite-dimensional -algebra with an identity. For an algebra , we denote by the category of finite-dimensional right -modules and by the standard duality on . An algebra is called self-injective if is an injective module, or equivalently, the projective modules in are injective. Two self-injective algebras and are said to be socle equivalent if the quotient algebras and are isomorphic. Symmetric algebras are an important class of self-injective algebras. An algebra is symmetric if there exists an associative, non-degenerate, symmetric, -bilinear form . Classical examples of symmetric algebras include in particular, blocks of group algebras of finite groups and Hecke algebras of finite Coxeter groups. In fact, any algebra is the quotient algebra of its trivial extension algebra , which is a symmetric algebra. By general theory, if is an idempotent of a symmetric algebra , then the idempotent algebra also is a symmetric algebra.
Brauer graph algebras play a prominent role in the representation theory of tame symmetric algebras. Originally, R. Brauer introduced the Brauer tree, which led to the description of blocks of group algebras of finite groups of finite representation type, and they are the basis for their classification up to Morita equivalence [10, 25, 29], see also [2]. Relaxing the condition on the characteristic of the field, one gets Brauer tree algebras, and these occurred in the Morita equivalence classification of symmetric algebras of Dynkin type [22, 35]. If one allows arbitrary multiplicities, and also an arbitrary graph instead of just a tree, one obtains Brauer graph algebras. These occurred in the classification of symmetric algebras of Euclidean type [7]. It was shown in [36] (see also [37]) that the class of Brauer graph algebras coincides with the class of symmetric special biserial algebras. Symmetric special biserial algebras occurred also in the Gelfand-Ponomarev classification of singular Harish-Chandra modules over the Lorentz group [23], and as well in the context of restricted Lie algebras, or more generally infinitesimal group schemes, [20, 21], and in classifications of tame Hecke algebras [3, 4, 14]. There are also results on derived equivalence classifications of Brauer graph algebras, and on the connection to Jacobian algebras of quivers with potential, we refer to [1, 11, 26, 31, 32, 34, 37].
We recall the definition of a Brauer graph algebra, following [36], see also [37]. A Brauer graph is a finite connected graph , with at least one edge (possibly with loops and multiple edges) such that for each vertex of , there is a cyclic ordering of the edges adjacent to , and there is a multiplicity which is a positive integer. Given a Brauer graph , one defines the associated Brauer quiver as follows:
- •
the vertices are the edges of ;
- •
there is an arrow in if and only if is the consecutive edge of in the cyclic ordering of edges adjacent to a vertex of .
In this case we say that the arrow is attached to . The quiver is 2-regular (see Section 2). Recall that a quiver is 2-regular if every vertex is the source and target of exactly two arrows. Any 2-regular quiver has a canonical involution on the arrows, namely if is an arrow the is the other arrow starting at the same vertex as .
The associated Brauer graph algebra is a quotient algebra of . The cyclic ordering of the edges adjacent to a vertex of translates to a cyclic permutation of the arrows in , and if is an arrow in this cycle, we denote vertex by . Let be the product of the arrows in the cycle, in the given order, starting with , this is an element in . The associated Brauer graph algebra is defined to be , where is the ideal in the path algebra generated by the elements:
- (1)
all paths of length in which are not subpaths of , 2. (2)
, for all arrows of .
In [17] and [18] we introduced and studied biserial weighted surface algebras, motivated by tame blocks of group algebras of finite groups. Given a triangulation of a 2-dimensional real compact surface, with or without boundary, and an orientation of triangles in , there is a natural way to define a quiver . We showed that these quivers have an algebraic description: they are precisely what we called triangulation quivers. A triangulation quiver is a pair where is a 2-regular quiver, and is a permutation of arrows of order such that for each arrow of . A biserial weighted surface algebra is then explicitly given by the quiver and relations, depending on a weight function , and if described using the triangulation quiver, we get a biserial weighted triangulation algebra (see Section 2).
Algebras of generalized dihedral type (see [18, Theorem 1]) which contain blocks with dihedral defect groups, turned out to be (up to socle deformation) idempotent algebras of biserial weighted surface algebras, for very specific idempotents. Biserial weighted surface algebras belong to the class of Brauer graph algebras. It is therefore a natural question to ask which other Brauer graph algebras occur as idempotent algebras of biserial weighted surface algebras. This is answered by our first main result.
Theorem 1**.**
Let be a basic, indecomposable, finite-dimensional -algebra over an algebraically closed field of dimension at least . Then the following statements are equivalent:
- (i)
* is a Brauer graph algebra.* 2. (ii)
* is isomorphic to the idempotent algebra for a biserial weighted surface algebra and an idempotent of .*
The main ingredient for this is Theorem 4.1. This gives a canonical construction, which we call -construction. A byproduct of the proof of Theorem 1 is the following fact.
Corollary 2**.**
Let be a Brauer graph algebra over an algebraically closed field . Then is isomorphic to the idempotent algebra of a biserial weighted surface algebra , for a surface without boundary, a triangulation of without self-folded triangles, and an idempotent of .
Moreover, we can adapt the -construction to algebras socle equivalent to Brauer graph algebras, and prove an analog for the main part of Theorem 1:
Theorem 3**.**
Let be a symmetric algebra over an algebraically closed field which is socle equivalent but not isomorphic to a Brauer graph algebra, and assume the Grothendieck group has rank at least . Then
- (i)
, and 2. (ii)
* is isomorphic to an idempotent algebra , where is a socle deformed biserial weighted surface algebra . Here is a surface with boundary, is a triangulation of without self-folded triangles, and is a border function.*
Recall that an algebra is called periodic if it is periodic with respect to action of the syzygy operator in the module category , where is its enveloping algebra. If is a periodic algebra of period then all indecomposable non-projective right -modules are periodic of period dividing , with respect to the syzygy operator in . Periodic algebras are self-injective, and have connections with group theory, topology, singularity theory and cluster algebras. In [17] and [19] we introduced and studied weighted surface algebras , which are tame, symmetric, and we showed that they are (with one exception) periodic algebras of period . They are defined by the quiver and explicitly given relations, depending on a weight function and a parameter function (see Section 6). Most biserial weighted surface algebras occur as geometric degenerations of these periodic weighted surface algebras.
Our third main result connects Brauer graph algebras with a large class of periodic weighted surface algebras.
Theorem 4**.**
Let be a Brauer graph algebra over an algebraically closed field . Then is isomorphic to an idempotent algebra of a periodic weighted surface algebra , for a surface without boundary, a triangulation of without self-folded triangles, and an idempotent of .
There are many idempotent algebras of weighted surface algebras which are neither Brauer graph algebras nor periodic algebras. We give an example at the end of Section 6.
This paper is organized as follows. In Section 2 we recall basic facts on special biserial algebras and show that Brauer graph algebras, symmetric special biserial algebras, and symmetric algebras associated to weighted biserial quivers are essentially the same. In Section 3 we introduce biserial weighted surface algebras and present their basic properties. In Section 4 we prove Theorem 1. This contains an algorithmic construction which may be of independent interest. Sections 5 and 6 contain the proofs of of Theorems 3 and 4, and related material. In the final Section 7 we present a diagram showing the relations between the main classes of algebras occurring in the paper.
For general background on the relevant representation theory we refer to the books [5, 13, 38, 40], and we refer to [13, 15] for the representation theory of arbitrary self-injective special biserial algebras.
2. Special biserial algebras
A quiver is a quadruple consisting of a finite set of vertices, a finite set of arrows, and two maps which associate to each arrow its source and its target . We denote by the path algebra of over whose underlying -vector space has as its basis the set of all paths in of length , and by the arrow ideal of generated by all paths in of length . An ideal in is said to be admissible if there exists such that . If is an admissible ideal in , then the quotient algebra is called a bound quiver algebra, and is a finite-dimensional basic -algebra. Moreover, is indecomposable if and only if is connected. Every basic, indecomposable, finite-dimensional -algebra has a bound quiver presentation , where is the Gabriel quiver of and is an admissible ideal in . For a bound quiver algebra , we denote by , , the associated complete set of pairwise orthogonal primitive idempotents of . Then the modules (respectively, ), , form a complete family of pairwise non-isomorphic simple modules (respectively, indecomposable projective modules) in .
Following [39], an algebra is said to be special biserial if is isomorphic to a bound quiver algebra , where the bound quiver satisfies the following conditions:
- (a)
each vertex of is a source and target of at most two arrows, 2. (b)
for any arrow in there are at most one arrow and at most one arrow with and .
Background on special biserial algebras may be found for example in [8, 13, 33, 39, 41]. Perhaps most important is the following, which has been proved by Wald and Waschbüsch in [41] (see also [8, 12] for alternative proofs).
Proposition 2.1**.**
Every special biserial algebra is tame.
If a special biserial algebra is in addition symmetric, there is a more convenient description. We propose the concept of a (weighted) biserial quiver algebra, which we will now define. Later, in Theorem 2.6 we will show that these algebras are precisely special biserial symmetric algebras.
Definition 2.2**.**
A biserial quiver is a pair , where is a finite connected quiver and is a permutation of the arrows of satisfying the following conditions:
- (a)
is 2-regular, that is every vertex of is the source and target of exactly two arrows, 2. (b)
for each arrow we have .
Let be a biserial quiver. We obtain another permutation defined by for any , so that and are the arrows starting at . Let be the -orbit of an arrow , and set . We denote by the set of all -orbits in . A function
[TABLE]
is said to be a weight function of . We write briefly for . The multiplicity function taking only value is said to be trivial. For any arrow , we single out the oriented cycle
[TABLE]
of length . The triple is said to be a (weighted) biserial quiver.
The associated biserial quiver algebra is defined as follows. It is the quotient algebra
[TABLE]
where is the ideal of the path algebra generated by the following elements:
- (1)
, for all arrows , 2. (2)
, for all arrows .
We assume that is not the quiver with one vertex and two loops and such that and are equal in , that is we exclude the 2-dimensional algebra isomorphic to . Assume , so that and are equal in . By the above assumption, lies in the square of the radical of the algebra. Then is not an arrow in the Gabriel quiver of , and we call it a virtual loop.
The following describes basic properties of (weighted) biserial quiver algebras.
Proposition 2.3**.**
Let be a weighted biserial quiver and . Then is a basic, indecomposable, finite-dimensional symmetric special biserial algebra with .
Proof.
It follows from the definition that is the special biserial bound quiver algebra , where is obtained from by removing all virtual loops, and where . Let be a vertex of and the two arrows starting at . Then the indecomposable projective -module has a basis given by together with all initial proper subwords of and , and and , and hence . Note also that the union of these bases gives a basis of consisting of paths in . We deduce that . As well, the indecomposable projective module has simple socle generated by . We define a symmetrizing -linear form as follows. If is a path in which belongs to the above basis, we set if for an arrow , and otherwise. Then for all elements and does not contain any non-zero one-sided ideal of , and consequently is a symmetric algebra (see [40, Theorem IV.2.2]). ∎
We wish to compare Brauer graph algebras and biserial quiver algebras. For this we start analyzing the combinatorial data. Let be a connected 2-regular quiver. We call a permutation of the arrows of admissible if for every arrow we have . That is, the arrows along a cycle of can be concatenated in . The multiplicity function of a Brauer graph taking only value is said to be trivial.
Lemma 2.4**.**
There is a bijection between Brauer graphs with trivial multiplicity function and pairs where is a connected 2-regular quiver, and is an admissible permutation of the arrows of .
Proof.
(1) Given , we take the quiver , as defined in the introduction.
(1a) We show that is 2-regular. Take an edge of , it is adjacent to vertices (which may be equal). If then the edge occurs both in the cyclic ordering around and of , so there are two arrows starting at , and there are two arrows ending at . If then the edge occurs twice in the cyclic ordering of edges adjacent to , so again there are two arrows starting at and two arrows ending at .
(1b) We define an (admissible) permutation on the arrows. Given , let be the vertex such that is attached to , then there is a unique edge adjacent to such that are consecutive edges in the ordering around , and hence a unique arrow , also ‘attached’ to , and we set . This defines an admissible permutation on the arrows. Writing as a product of disjoint cycles, gives a bijection between the cycles of and the vertices of . Namely, let the cycle of correspond to if it consists of the arrows attached to .
(2) Suppose we are given a connected 2-regular quiver and an admissible permutation , written as a product of disjoint cycles. Define a graph with vertices the cycles of , and edges the vertices of . Each cycle of defines a cyclic ordering of the edges adjacent to the vertex corresponding to this cycle. Hence we get a Brauer graph.
(3) It is clear that these give a bijection. ∎
Remark 2.5**.**
In part (1b) of the above proof, we may have . There are two such cases. If the edge is adjacent to two distinct vertices of then is the only edge adjacent to a vertex and we have . We call an external loop. Otherwise the edge is a loop of , and then . In this case the cycle of passes twice through vertex of the quiver. We call an internal loop.
The Brauer graph comes with a multiplicity function defined on the vertices. Given , we take the same multiplicity function, defined on the cycles of , which gives the function which we have called a weight function. The permutation determines the permutation of the arrows where for any arrow . Clearly is also admissible, and and determine each other.
We have seen that the combinatorial data for are the same as the combinatorial data for . Therefore is in fact equal to .
In the definition of a biserial quiver we focus on , this is motivated by the connection to biserial weighted surface algebras, which we will define later.
The following compares various algebras. The equivalence of the statements (i) and (iii) was already obtained by Roggenkamp in [36, Sections 2 and 3] (see also [1, Proposition 1.2] and [37, Theorem 1.1]). We include it, for completeness.
Theorem 2.6**.**
Let be a basic, indecomposable algebra of dimension at least , over an algebraically closed field . The following are equivalent:
- (i)
* is a Brauer graph algebra.* 2. (ii)
* is isomorphic to an algebra where is a (weighted) biserial quiver.* 3. (iii)
* is a symmetric special biserial algebra.*
Proof.
As we have just seen, (i) and (ii) are equivalent. The implication (ii) (iii) follows from Proposition 2.3.
We prove now (iii) (ii). Assume that is a basic symmetric special biserial algebra, let where is the Gabriel quiver of . We will define a (weighted) biserial quiver and show that is isomorphic to . Since is special biserial, for each vertex of , we have and . The algebra is symmetric, therefore for each vertex , we have : Namely, if then by the special biserial relations, the projective module is uniserial. It is isomorphic to the injective hull of the simple module , and hence . If then by the same reasoning, applied to it follows that .
Let , to each we adjoin a loop at to the quiver , which then gives a 2-regular quiver. Explicitly, let with and is the disjoint union
We define a permutation of . For each , there are unique arrows and in with , and we set and . If is any arrow of with not in , we define to be the unique arrow in with . With this, is a biserial quiver.
We define now a weight function , where . For each , we have , and we set . Let be some arrow of starting at vertex , and let . Since is symmetric special biserial, there exists such that
[TABLE]
is a maximal cyclic path in which does not belong to , and spans the socle of the indecomposable projective module . The integer is constant on the -orbit of and we may define .
It remains to show that by suitable scaling of arrows one obtains the stated relations involving paths . Fix a symmetrizing linear form for . Fix an orbit of , say , there is a non-zero scalar such that for all arrows in this orbit we have
[TABLE]
We may assume . Namely, we can choose in an arrow, say, and replace it by where . The cycles are disjoint, and if we do this for each cycle then we have for all arrows .
Let be a vertex of with , and let be the two arrows starting at . Then there are non-zero scalars and such that in . Then we have
[TABLE]
Hence we can cancel these scalars and obtain the required relations. With this, there is a canonical isomorphism of -algebras . ∎
We will from now suppress the word ’weighted’, in analogy to the convention for Brauer graph algebras, where the multiplicity function is part of the definition but is not explicitly mentioned.
We will study idempotent algebras, and it is important that any idempotent algebra of a special biserial symmetric algebra is again special biserial symmetric.
Proposition 2.7**.**
Let be a symmetric special biserial algebra. Assume is an idempotent of which is a sum of some of the associated to vertices of . Then also is a symmetric special biserial algebra.
Proof.
We may assume that for a weighted biserial quiver and is indecomposable, and let . We will show that for a weighted biserial quiver . We define to be the set of all vertices such that is the sum of the primitive idempotents . For each arrow with , we denote by the shortest path in of the form with and . Such a path exists because is a cycle around vertex in . Then we define to be set of paths in for all arrows with . Moreover, for , we set and . This defines a -regular quiver . Further, for each arrow in , there is exactly one arrow in such that and , and we set . This defines a biserial quiver . Let be the permutation of associated to , and the set of -orbits in . Then we define the weight function of by setting for each arrow . With these, the biserial quiver algebra is isomorphic to . ∎
We end this section with an example illustrating Theorem 2.6. This also shows that an idempotent algebra of a Brauer graph algebra need not be indecomposable, by taking .
Example 2.8**.**
Let be the Brauer graph
[TABLE]
where we take the clockwise ordering of the edges around each vertex. Then is the symmetric algebra with biserial quiver
[TABLE]
where the -orbits are , , . Then the -orbits are , , ,
[TABLE]
The weight function is as before given by the multiplicity function of the Brauer graph . We note that and , and .
3. Biserial weighted surface algebras
In this section we introduce biserial weighted surface algebras and describe their basic properties.
In this paper, by a surface we mean a connected, compact, -dimensional real manifold , orientable or non-orientable, with boundary or without boundary. It is well known that every surface admits an additional structure of a finite -dimensional triangular cell complex, and hence a triangulation (by the deep Triangulation Theorem (see for example [9, Section 2.3])).
For a positive natural number , we denote by the unit disk in the -dimensional Euclidean space , formed by all points of distance from the origin. Then the boundary of is the unit sphere in , formed by all points of distance from the origin. Further, by an -cell we mean a topological space homeomorphic to the open disk . In particular, consists of two points. Moreover, we define to be a point.
We refer to [24, Appendix] for some basic topological facts about cell complexes.
Let be a surface. In the paper, by a finite -dimensional triangular cell complex structure on we mean a finite family of continuous maps , with and , satisfying the following conditions:
- (1)
Each restricts to a homeomorphism from to the -cell of , and these cells are all disjoint and their union is . 2. (2)
For each -dimensional cell , is the union of -cells and [math]-cells, with and .
Then the closures of all -cells are called triangles of , and the closures of all -cells are called edges of . The collection of all triangles is said to be a triangulation of . We assume that such a triangulation of has at least two different edges, or equivalently, there are at least two different -cells in the considered triangular cell complex structure on . Then is a finite collection of triangles of the form
[TABLE]
such that every edge of such a triangle in is either the edge of exactly two triangles, is the self-folded edge, or lies on the boundary. We note that a given surface admits many finite -dimensional triangular cell complex structures, and hence triangulations. We refer to [9, 27, 28] for general background on surfaces and constructions of surfaces from plane models.
Let be a surface and a triangulation . To each triangle in we may associate an orientation
[TABLE]
if has pairwise different edges , and
[TABLE]
if is self-folded, with the self-folded edge , and the other edge . Fix an orientation of each triangle of , and denote this choice by . Then the pair is said to be a directed triangulated surface. To each directed triangulated surface we associate the quiver whose vertices are the edges of and the arrows are defined as follows:
- (1)
for any oriented triangle in with pairwise different edges , we have the cycle
[TABLE] 2. (2)
for any self-folded triangle in , we have the quiver
[TABLE] 3. (3)
for any boundary edge in , we have the loop
[TABLE]
Then is a triangulation quiver in the following sense (introduced independently by Ladkani in [30]).
A triangulation quiver is a pair , where is a finite connected quiver and is a permutation on the set of arrows of satisfying the following conditions:
- (a)
every vertex is the source and target of exactly two arrows in , 2. (b)
for each arrow , we have , 3. (c)
is the identity on .
Hence, a triangulation quiver is a biserial quiver such that is the identity.
For the quiver of a directed triangulated surface , the permutation on its set of arrows is defined as follows:
- (1)
[TABLE] \textstyle{a\ignorespaces\ignorespaces\ignorespaces\ignorespaces}$$\scriptstyle{\alpha}$$\textstyle{b\ignorespaces\ignorespaces\ignorespaces\ignorespaces}$$\scriptstyle{\beta}$$\textstyle{c\ignorespaces\ignorespaces\ignorespaces\ignorespaces}$$\scriptstyle{\gamma} , , ,
for an oriented triangle in , with pairwise different edges , 2. (2)
\textstyle{a\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces}$$\scriptstyle{\alpha}$$\scriptstyle{\beta}$$\textstyle{b\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces}$$\scriptstyle{\gamma}
, , ,
for a self-folded triangle in , 3. (3)
\textstyle{a\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces\ignorespaces}$$\scriptstyle{\alpha}
,
for a boundary edge of .
If is a triangulation quiver, then the quiver is -regular. We will consider only the triangulation quivers with at least two vertices. Note that different directed triangulated surfaces (even of different genus) may lead to the same triangulation quiver (see [17, Example 4.4]).
The following theorem is a slightly stronger version of [17, Theorem 4.11] (see also [18, Example 8.2] for the case with two vertices).
Theorem 3.1**.**
Let be a triangulation quiver with at least two vertices. Then there exists a directed triangulated surface such that is orientable, is a coherent orientation of triangles in , and .
Proof.
This is a minor adjustment of the proof of Theorem 4.11 in [17] which we will now present. We denote by the number of -orbits in of length . Note that because has at least two vertices. There is exactly one triangulation quiver with two vertices, namely
[TABLE]
with , , , , and it is the triangulation quiver associated to the self-folded triangulation of the disk
[TABLE]
with a boundary edge. It is also known that the theorem holds for all triangulation quivers with three vertices (see [18, Examples 4.3 and 4.4] and Example 4.6). Therefore, we may assume that and has at least four vertices. Now our induction assumption is: For any triangulation quiver with at least two vertices and there exists a directed triangulated surface such that is orientable, is a coherent orientation of triangles in , and . Then we proceed as in the reconstruction steps (1) and (2) of the proof of [17, Theorem 4.11], with the following adjustments. In step (1), we replace the projective plane by the disk with self-folded triangulation, described above. In step (2), we glue the oriented triangle
[TABLE]
with pairwise different edges, in a coherent way with the corresponding triangles of the directed triangulated surface , constructed in this step. ∎
Remark 3.2**.**
There is an alternative proof of Theorem 3.1. According to Lemma 2.4 and Theorem 2.6, we may associate to a triangulation quiver a Brauer graph with trivial multiplicity function such that , where is the trivial weight function of . In the Brauer graph , the vertices correspond to the -orbits in and the edges to the vertices of . Thickening the edges of we obtain an oriented surface whose border is given by the faces of , corresponding to the -orbits in . Since is a triangulation quiver, the faces are either triangles or (internal) loops. Capping now all triangle faces by disks we obtain a directed triangulated surface such that .
Remark 3.3**.**
We would like to stress that the setting of directed triangulated surfaces is natural for the purposes of a self-contained representation theory of symmetric tame algebras of non-polynomial growth which we are currently developing. In particular, this gives the option of changing orientation of any triangle independently, keeping the same surface and triangulation.
Let be a triangulation quiver, this is in particular a biserial quiver as introduced in Definition 2.2. With the same notation, for a weight function a weight function , the associated weighted biserial quiver algebra
[TABLE]
is said to be a biserial weighted triangulation algebra. Moreover, if for a directed triangulation surface , then is called a biserial weighted surface algebra, and denoted by (see [17] and [18]).
Biserial weighted surface algebras belong to the class of algebras of generalized dihedral type, which generalize blocks of group algebras with dihedral defect groups. They are introduced and studied in [18]. We end this section by giving two examples of biserial weighted surface algebras.
Example 3.4**.**
Consider the disk with the triangulation and orientation of triangles in as follows
[TABLE]
Then the associated triangulation quiver is of the form
[TABLE]
with -orbits , , , . Then the -orbits are and . Hence a weight function is given by two positive integers and . Then the associated biserial weighted surface algebra is given by the above quiver and the relations:
[TABLE]
Example 3.5**.**
Consider the torus with the triangulation and orientation of triangles in as follows
[TABLE]
Then the associated triangulation quiver is of the form
[TABLE]
with -orbits and . Then has only one orbit which is , and hence a weight function is given by a positive integer . Then the associated biserial weighted surface algebra is given by the above quiver and the relations:
[TABLE]
The triangulation quiver is called the ‘Markov quiver’ (see [18] for a motivation).
4. Proof of Theorem 1
To prove the implication (ii) (i), let be a biserial weighted surface algebra. Then by Theorem 3.1 we may assume where is a biserial quiver and is the identity. Then in particular is a biserial quiver algebra, and by Theorem 2.6, we see that is a Brauer graph algebra. Now it follows from Theorem 2.6 and Proposition 2.7 that also is a Brauer graph algebra, and (i) holds.
We consider the implication (i) (ii). Assume is a Brauer graph algebra, by Theorem 2.6 we may assume where is a biserial quiver. To obtain (ii), we must find a biserial quiver with such that where and an idempotent of .
The following shows that this can be done in a canonical way, the construction gives an algorithm. Furthermore, applying the construction twice gives an interesting consequence.
Theorem 4.1**.**
Let be a biserial quiver algebra. Then there is a canonically defined weighted triangulation quiver such that the following statements hold.
- (i)
* is isomorphic to the idempotent algebra of the biserial triangulation algebra with respect to a canonically defined idempotent of .* 2. (ii)
The triangulation quiver has no loops fixed by . 3. (iii)
The triangulation quiver has no loops and self-folded triangles. 4. (iv)
* is isomorphic to the idempotent algebra of the biserial triangulation algebra with respect to a canonically defined idempotent of .*
Proof.
Let , and let be the permutation of associated to . We define a triangulation quiver as follows. We take with
[TABLE]
and , , , , , . Moreover, we set , , . We observe that is a triangulation quiver. Let be the permutation of associated to . We notice that, for any arrow of , we have , , and . For each arrow , we denote by the -orbit of . Then the -orbits in are
[TABLE]
for , where is the length of the -orbit of and is the length of the -orbit of in . We define the weight function by and for all .
Let be the biserial triangulation algebra associated to and let be the sum of the primitive idempotents in associated to all vertices . Using the proof of Proposition 2.7 we see directly that the idempotent algebra is isomorphic to . It follows also from the definition of that has no loops fixed by , and (ii) holds. In particular, we conclude that for any arrow . Hence, the triangulation quiver has no loops, and consequently it has also no self-folded triangles, and (iii) follows. Finally, by (i), is isomorphic to an idempotent algebra of for the corresponding idempotent of . Taking , we obtain that is isomorphic to the idempotent algebra , and hence (iv) also holds. ∎
We give some illustrations for the -construction.
(1) A loop in fixed by is replaced in by the subquiver
[TABLE]
with the -orbit .
(2) A subquiver of of the form
[TABLE]
where is an -orbit, is replaced in by the quiver
[TABLE]
with -orbits , and .
(3) A subquiver of of the form
[TABLE]
and where is an -orbit, is replaced in by the quiver of the form
[TABLE]
with -orbits , , and .
Remark 4.2**.**
The statement (i) of the above theorem also holds if we replace the canonically defined weight function by a weight function such that and is an arbitrary positive integer, for any arrow .
Remark 4.3**.**
The construction of the triangulation quiver associated to is canonical, though a quiver with fewer vertices may often be sufficient. In fact, it would be enough to apply the construction only to the arrows in -orbits of length different from and . An algebra may have many presentations as an idempotent algebra of some biserial triangulation algebra, even for a triangulation quiver with fewer -orbits than the number of -orbits in the triangulation quiver (see Example 4.7).
Remark 4.4**.**
The -construction described in Theorem 4.1 provides a special class of triangulation quivers. Namely, let be a biserial quiver, the permutation of associated to , and the permutation of associated to . Then, for every arrow , we have in the -orbit of even length and the -orbit whose length is the length of the -orbit of in . In particular, all triangulation quivers having only -orbits of odd length do not belong to this class of triangulation quivers. For example, it is the case for the tetrahedral quiver considered in Section 6. We refer also to [17, Example 4.9] for an example of triangulation quiver for which all arrows in belong to one -orbit of length .
Example 4.5**.**
Let be the Brauer tree
[TABLE]
with multiplicity function and . Then the associated Brauer graph algebra is the algebra associated to the biserial quiver where is of the form
[TABLE]
with , , , , and , and . If , then is the truncated polynomial algebra . The associated triangulation quiver is of the form
[TABLE]
and the -orbits are and . Further, the -orbits are , , and the weight function is , , . We also note that is the triangulation quiver associated to the torus with triangulation and orientation of triangles in as follows
[TABLE]
(compare with Example 3.5).
Example 4.6**.**
Let be the Brauer graph
[TABLE]
with multiplicity for some . Then the associated Brauer graph algebra is the algebra where the quiver is of the form
[TABLE]
with , , , , and . The associated triangulation quiver is
[TABLE]
with -orbits and . Further, the -orbits are , , , and , , . Note that is the triangulation quiver associated to the sphere with triangulation given by two self-folded triangles
[TABLE]
where is canonically defined.
Example 4.7**.**
Let be the weighted biserial quiver considered in Example 2.8. Then the triangulation quiver is of the form
[TABLE]
where the shaded triangles describe the -orbits in . Then we have the following -orbits in :
[TABLE]
Moreover, the weight function is given by
[TABLE]
Finally, . We note that has -orbits, all of length three.
The Brauer graph algebra is also isomorphic to the idempotent algebra of a biserial triangulation algebra for the triangulation quiver shown below
[TABLE]
with -orbits described by the shaded triangles (all of length three), a weight function of , and where the idempotent is the sum of the primitive idempotents in associated to the vertices .
We finish this section with a combinatorial interpretation of the -construction in terms of Brauer graphs.
4.8. Barycentric division of Brauer graphs.
Let be the Brauer graph so that , then the algebra as in the -construction of Theorem 4.1 is again a Brauer graph algebra, say, by Theorem 2.6. The proof of Lemma 2.4 shows how to construct : Its vertices are in bijection with the cycles of . First, each cycle of is ‘augmented’, by replacing an arrow by , and this gives a cycle of , we call a corresponding vertex of an augmented vertex. Second, any other cycle of consists of -arrows, and these cycles correspond to -cycles of , as described in Theorem 4.1. Let be the -orbit of in , then we write for the corresponding vertex of , then the arrows attached to this vertex are precisely the .
The edges of are labelled by the vertices of , that is by the vertices of together with the set . The cyclic order around an augmented vertex is obtained by replacing by
[TABLE]
in . A vertex has attached arrows precisely the . This specifies the edges adjacent, with cyclic order given by the inverse of the -cycle of . We may view as a ‘triangular’ graph:
(1) Assume that . Then is the unique edge in adjacent to , and is its own successor in the cyclic order of edges in around . Hence we have in a self-folded triangle
[TABLE]
which corresponds to a subquiver of of the form
[TABLE]
with -orbit .
(2) Assume that , and let starting at vertex . Let be the vertices in such that is attached to and is attached to . Then has edges and connecting vertices and to vertex . Then is the successor of in the cyclic order of edges in around . Hence we have in a triangle
[TABLE]
which corresponds to a subquiver of of the form
[TABLE]
with -orbit . The multiplicity function of is given by for any vertex of (where is the multiplicity function for ), and for any -orbit .
The Brauer graph can be considered as a barycentric division of the Brauer graph , and has a triangular structure. Namely, every is the vertex of triangles in whose edges opposite to are the edges of corresponding to the vertices in along .
In this way, we obtain an orientable surface without boundary, the triangulation of indexed by the set of edges of , and the orientation of triangles in such that the associated triangulation quiver is the quiver . The triangulated surface can be considered as a completion of the Brauer graph to a canonically defined triangulated surface, by a finite number of pyramids whose peaks are the -orbits and bases are given by the edges of . We also note that the surface (without triangulation ) can be obtained as follows. We may embed the Brauer graph into a surface with boundary given by thickening the edges of . The components of the border of are given by the ‘Green walks’ around on , corresponding to the -orbits in . Then the surface is obtained from by capping all the boundary components of by the disks .
Example 4.9**.**
Let be the Brauer graph
[TABLE]
where we take the clockwise ordering of edges around each vertex. Assume the multiplicity function takes only value . Then the associated biserial quiver is of the form
[TABLE]
with -orbits
[TABLE]
and consisting of
[TABLE]
Then the barycentric division of is the Brauer graph
[TABLE]
with , and . The ordering of the edges around each vertex is clockwise. The multiplicity function of takes only the value .
The Brauer graph admits a canonical embedding into the surface of the form
[TABLE]
obtained from by thickening the edges of , whose border has three components given by three different
‘Green walks’ around on . The triangulated surface associated to the Brauer graph can be viewed as a canonical completion of to a triangulated surface.
5. Proof of Theorem 3
This theorem describes algebras socle equivalent to Brauer graph algebras. By Theorem 2.6 this is the same as describing algebras socle equivalent to a biserial quiver algebra where is a biserial quiver. We show that such algebras can be described using the methods of [18, Section 6]. Then we show that the -construction for the biserial quiver algebras can be extended.
Let be a biserial quiver. A vertex is said to be a border vertex of if there is a loop at with . We denote by the set of all border vertices of , and call it the border of . The terminology is motivated by the connection with surfaces: If is the triangulation quiver associated to a directed triangulated surface , then the border vertices of correspond bijectively to the boundary edges of the triangulation of . If is the biserial quiver associated to a Brauer graph , then the border vertices of correspond bijectively to the internal loops of (see Section 2).
Definition 5.1**.**
Assume is a biserial quiver with not empty. A function
[TABLE]
is said to be a border function of . We have the quotient algebra
[TABLE]
where is the ideal in the path algebra generated by the elements:
- (1)
, for all arrows which are not border loops, 2. (2)
, for all border loops , 3. (3)
, for all arrows .
We call such an algebra a biserial quiver algebra with border. Note that if is the zero function then .
We summarize the basic properties of these algebras.
Proposition 5.2**.**
Let be a biserial quiver such that is not empty, and let , and where and are weight and border functions. Then the following statements hold.
- (i)
* is a basic, indecomposable, finite-dimensional, symmetric, biserial algebra with .* 2. (ii)
* is socle equivalent to .* 3. (iii)
If is of characteristic different from , then is isomorphic to .
Proof.
Part (ii) is clear from the definition and then part (i) follows from Proposition 2.3. For the last part see arguments in the proof of Proposition 6.3 in [18]. ∎
The following theorem gives a complete description of symmetric algebras socle equivalent to a biserial quiver algebra.
Theorem 5.3**.**
Let be a basic, indecomposable, symmetric algebra with Grothendieck group of rank at least . Assume that is socle equivalent to a biserial quiver algebra .
- (1)
If is empty then is isomorphic to . 2. (2)
Otherwise is isomorphic to for some border function of .
Proof.
Let where . Since is isomorphic to , we can assume that these are equal, using an isomorphism as identification. We assume is symmetric, therefore for each , the module has a 1-dimensional socle which is spanned by some , and we fix such an element. Then let be a symmetrizing linear form for , then is non-zero. We may assume that .
We claim that . If not, then for some we have . This means that , which is not possible since is indecomposable with at least two simple modules. It follows that and have the same Gabriel quiver. Recall that the quiver is the disjoint union of the Gabriel quiver of with virtual loops. Any virtual loop of is then in the socle of and it is zero in and is therefore zero in . We may therefore take of the form for the same quiver , and some ideal of , and such that any virtual loop lies in the socle of .
In the algebra we define monomials in the arrows by setting when is not a virtual loop, and then as well . Note that if is a virtual loop then is not defined. With this, the elements belong to the socle of and hence also to the socle of . Therefore they cannot lie in the socle of (because if so then they would be zero in ). Then where . We have that is spanned by
[TABLE]
where and .
(I) We may assume that in (and hence is equal to in ).
If not, then we have , and then . We will show that we may interchange and .
Since , in particular and also . Since we know that belongs to the socle of . It is non-zero, which implies that (and ), and therefore , and . We claim that . Namely if we had then both and would be loops at vertex and , which contradicts our assumption. Hence the cycle of containing is , of length two. We claim that also the -cycle of (in ) has length two. Namely if is the other arrow starting at and is the other arrow ending at then we must have by the properties of and that and . This implies that and hence has a cycle .
It follows that there is an algebra isomorphism from to the biserial quiver algebra given by the weighted biserial quiver obtained from by interchanging and (which form a pair of double arrows) and fixing all other arrows of . We replace by and the claim follows.
(II) We show that relation (1) holds in . If is a virtual loop of then since . We consider now an arrow which is not a virtual loop. Suppose is not fixed by , then belongs to the socle of . We can write for some (here is not a virtual loop).
(a) If then , in fact this holds for any choice of .
(b) Otherwise, we set
[TABLE]
and we replace by . (If a cycle of has a virtual loop then and are not cyclic paths, so they are zero and do not need adjusting.) These modifications must be iterated. Take a cycle of , say it has length , so that .
Assume first this cycle contains an arrow such that is not a cyclic path. We may start with and adjust as described above. Then , by (a) above.
Otherwise, for any in the cycle, is cyclic, and then we must have or . Assume that . We adjust as described in (b) and have in , and we must show that as well . By the assumption, for some . We have
[TABLE]
Assume now that . Since is -regular, is of the form
[TABLE]
with -orbit and -orbit . We adjust as in (b) to have , , . By assumption we have for some and . We replace by and obtain . Observe that we have also , because .
(III) We show that relation (3) holds in . For each arrow , we have for some . We claim that for any arrow in the -orbit of . Indeed, if belongs to , then
[TABLE]
Since is algebraically closed, we may choose such that . Replacing now the representative of each arrow in by its product with , we obtain a new presentation such that for any arrow . This does not change the relations (1) obtained above. Therefore, we may assume that, if is any vertex, and are the arrows in with source , then in .
(IV) We show that relation (2) holds in . When the border of is empty, there is nothing to do (and is isomorphic to ). Assume now that is not empty. Then for any loop with , we have for some . Hence, we have a border function , and is isomorphic to the algebra . ∎
Recall that a self-injective algebra is biserial if the radical of any indecomposable non-uniserial projective, left or right, -module is a sum of two uniserial modules whose intersection is simple.
Theorem 3 follows from Theorems 2.6, 3.1, 5.3 and the following relative version of Theorem 4.1 (see Remark 4.3).
Theorem 5.4**.**
Let where has at least two vertices, and where the border is not empty. Then there is a canonically defined weighted triangulation quiver such that the following statements hold.
- (i)
. 2. (ii)
* is isomorphic to the idempotent algebra of the biserial weighted triangulation algebra with respect to a canonically defined idempotent of .* 3. (iii)
For any border function of and the induced border function of , the algebras and are isomorphic.
Proof.
The construction of is analogous to the -construction in Theorem 4.1. We take the notation as in Theorem 4.1 and in addition we denote by the set of all border loops of the quiver. We define a triangulation quiver as follows. We take with
[TABLE]
for all loops , and , , , , , , for any arrow . Moreover, we set for any loop , and , , , for any arrow . We observe that is a triangulation quiver with . Let be the permutation of associated to . For each arrow in , we denote by the -orbit of in . Then the -orbits in are
[TABLE]
for any loop , and
[TABLE]
for any arrow (where is the length of the -orbit of ). We define the weight function by for any loop , and and for any arrow .
Let be the biserial weighted triangulation algebra associated to and the sum of the primitive idempotents in associated to the vertices . Then it follows from the arguments as in the proof of Proposition 2.7 that is isomorphic to the idempotent algebra . Moreover, let be a border function of and be the induced border function of , that is for any border vertex . Then it follows from the description of -orbits in and the definition of the weight function that is isomorphic to the idempotent algebra . ∎
Example 5.5**.**
This illustrates the -construction in Theorem 5.4. Let be the biserial quiver
[TABLE]
with -orbits , , , , . Then the border of is the set of all vertices of , and are the border loops. Further, has only one orbit, . We take the weight function with . Moreover, let be a border function. Then we describe the associated algebra . It has quiver , and to simplify the notation for the relations, we use the notion of for an arrow , as it has appeared throughout,
[TABLE]
Note that the algebra is given by the quiver and the above relations such that all are zero. By the arguments as in [18, Example 6.5], if has characteristic and is non-zero, then the algebras and are not isomorphic.
The triangulation quiver is of the form
[TABLE]
with -orbits , , , , , , , . Further, there are two -orbits:
[TABLE]
The weight function takes only value , and the border function is , , , .
(a) The relations from vertex 1 are
[TABLE]
There are analogous relations from each of the vertices .
(b) The relations from vertex are
[TABLE]
There are analogous relations from each of the vertices .
We observe now that is isomorphic to the idempotent algebra where the idempotent is the sum of the primitive idempotents at the vertices . Moreover, the algebras and are also isomorphic. Finally, we note that if has characteristic and is non-zero, then the algebras and are not isomorphic.
6. Proof of Theorem 4
We recall the definition of a weighted triangulation algebra. Let be a triangulation quiver with at least two vertices, and let , and be defined as for biserial quiver algebras. The additional datum is a function
[TABLE]
which we call a parameter function of . We write briefly and for . The parameter function taking only value is said to be trivial. We assume that for any arrow . For any arrow , define the path
[TABLE]
in of length . Then we have
[TABLE]
of length . Then, following [17], we define the bound quiver algebra
[TABLE]
where is the admissible ideal in the path algebra of over generated by the elements:
- (1)
, for all arrows , 2. (2)
, for all arrows .
The algebra is called a weighted triangulation algebra of . Moreover, if for a directed triangulated surface , then is called a weighted surface algebra, and if the surface and triangulation is important we denote the algebra by .
We note that the Gabriel quiver of is equal to , this holds because we assume for all arrows .
We have the following proposition (see [17, Proposition 5.8]).
Proposition 6.1**.**
Let be a triangulation quiver, and weight and parameter functions of . Then is a finite-dimensional tame symmetric algebra of dimension .
We have also the following theorem proved in [17, Theorem 1.2] (see also [6, Proposition 7.1] and [16, Theorem 5.9] for the case of two vertices).
Theorem 6.2**.**
Let be a weighted surface algebra over an algebraically closed field . Then the following statements are equivalent:
- (i)
All simple modules in are periodic of period . 2. (ii)
* is a periodic algebra of period .* 3. (iii)
* is not isomorphic to a singular tetrahedral algebra.*
Following [17], a singular tetrahedral algebra is the weighted surface algebra given by a coherent orientation of four triangles of the tetrahedron and the weight and parameter functions taking only value . The triangulation quiver of such algebra is the tetrahedral quiver of the form
[TABLE]
where the shaded triangles denote -orbits and white triangles denote -orbits.
The following theorem is an essential ingredient for the proof of Theorem 4.
Theorem 6.3**.**
Let be a biserial weighted triangulation algebra where has no loops, and the weighted triangulation algebra associated to the weighted triangulation quiver and the trivial parameter function of . Then the following statements hold:
- (i)
* is a periodic algebra of period .* 2. (ii)
* is isomorphic to the idempotent algebra for an idempotent of .*
Proof.
For each arrow in , we set and . We observe first that , and hence , for any arrow in , and consequently is a well defined weighted triangulation algebra. Indeed, it follows from Theorem 4.1(iii) that the triangulation quiver has neither loops nor self-folded triangles. Moreover, the -orbits in have length , and the -orbits in are of length at least . Then it follows from the proof of Theorem 4.1 that the -orbits in are
[TABLE]
for all arrows . Then the required inequalities hold. Further, it follows from Remark 4.4 that is not the tetrahedral quiver. Then, applying Theorem 6.2, we conclude that is a periodic algebra of period .
Let be the sum of all primitive idempotents in corresponding to the vertices of . We claim that is isomorphic to . Observe that every -orbit in creates in the subquiver as in the illustration (3) following Theorem 4.1. The algebra has arrows , , , and it follows that in we have
[TABLE]
Further, let be a vertex of , and let and the two arrows in with source . By the proof of Theorem 4.1, the -orbits are
[TABLE]
Moreover, and . Hence we have in the cycles
[TABLE]
and in (see [17, Lemma 5.3]), and this gives the equality in . Therefore, is isomorphic to . ∎
We may now complete the proof of Theorem 4. Let be a biserial quiver algebra. Then it follows from Theorem 4.1 that is isomorphic to the idempotent algebra of the biserial triangulation algebra for some idempotent of , and has no loops. Applying now Theorem 6.3 we conclude that is isomorphic to the idempotent algebra of a periodic weighted triangulation algebra, for an idempotent of . Since is a summand of , we have . Then Theorem 4 follows from Theorems 2.6 and 3.1.
Remark 6.4**.**
Let be a weighted triangulation algebra. Then the biserial triangulation algebra is not an idempotent algebra of . On the other hand, if is not a tetrahedral algebra, then is a geometric degeneration of (see [17, Proposition 5.8]).
Example 6.5**.**
Let be the Markov quiver in Example 3.5 and a positive integer associated to the unique -orbit in . Then the associated weighted triangulation algebra with trivial parameter function is given by the quiver and the following relations (we write the indices modulo 3):
[TABLE]
The idempotent algebra of with respect to the primitive idempotent at vertex is isomorphic to the Brauer graph algebra given by the Brauer graph in Example 4.6.
According to Theorem 4.1 we have the triangulation quiver
[TABLE]
where the shaded triangles denote the -orbits in . The -orbits in are
[TABLE]
The weight function is given by , , . We define the parameter function to be the constant function with value . The weighted triangulation algebra is given by the above quiver and with commutativity relations and zero-relations, corresponding to the six -orbits in . For example, we have the relations given by the -orbit :
[TABLE]
The biserial weighted triangulation algebra is then isomorphic to the idempotent algebra , where is the sum of the primitive idempotents in corresponding to the vertices .
We present now an example of an idempotent algebra of a periodic weighted surface algebra which is neither a Brauer graph algebra nor a weighted surface algebra.
Example 6.6**.**
Let be a triangle with one puncture, the triangulation of
[TABLE]
such that the edges are on the boundary, and let be the orientation of triangles of : , , . Then the triangulation quiver is of the form
[TABLE]
with -orbits , , , , , . Hence we have two -orbits:
[TABLE]
Take the weight function given by and . Moreover, let be the trivial parameter function. Then the associated weighted surface algebra is given by the quiver and the relations:
[TABLE]
Let be the sum of primitive idempotents of at the vertices , and the associated idempotent algebra. Then is given by the quiver of the form
[TABLE]
with the arrows and , and the induced relations:
[TABLE]
Then is not a special biserial algebra, and therefore it is not a Brauer graph algebra. Further, is not a weighted surface algebra, because we have zero-relations and of length . On the other hand, by general theory, the algebra is tame and symmetric.
7. Diagram of algebras
The following diagram shows the relations between the main classes of algebras occurring in the paper.
[TABLE]
where, for a weighted biserial quiver algebra , , and , with denoting the trivial weight function of .
Acknowledgements
The results of the paper were partially presented during the Workshop on Brauer Graph Algebras held in Stuttgart in March 2016. The paper was completed during the visit of the first named author at the Faculty of Mathematics and Computer Science of Nicolaus Copernicus University in Toruń (June 2017).
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1[1] T. Aihara , Derived equivalences between symmetric special biserial algebras, J. Pure Appl. Algebra 219 (2015), 1800–1825.
- 2[2] J. L. Alperin , Local Representation Theory, Cambridge Stud. Adv. Math. 11 , Cambridge Univ. Press, Cambridge 1986.
- 3[3] S. Ariki , K. Iijima and E. Park , Representation type of finite quiver Hecke algebras of type A ℓ ( 1 ) subscript superscript 𝐴 1 ℓ A^{(1)}_{\ell} for arbitrary parameters, Int. Math. Res. Not. IMRN 15 (2015), 6070–6135.
- 4[4] S. Ariki and E. Park , Representation type of finite quiver Hecke algebras of type D ℓ + 1 ( 2 ) subscript superscript 𝐷 2 ℓ 1 D^{(2)}_{\ell+1} , Trans. Amer. Math. Soc. 368 (2016), 3211–3242.
- 5[5] I. Assem , D. Simson and A. Skowroński , Elements of the Representation Theory of Associative Algebras 1: Techniques of Representation Theory, London Math. Soc. Student Texts 65 , Cambridge University Press, Cambridge 2006.
- 6[6] J. Białkowski , K. Erdmann and A. Skowroński , Periodicity of self-injective algebras of polynomial growth, J. Algebra 443 (2015), 200–269.
- 7[7] R. Bocian and A. Skowroński , Symmetric special biserial algebras of Euclidean type, Colloq. Math. 96 (2003), 121–148.
- 8[8] M. C. R. Butler and C. M. Ringel , Auslander-Reiten sequences with few middle terms and applications to string algebras, Comm. Algebra 15 (1987), 145–179.
