Semi-invariant of a quiver

In mathematics, given a quiver Q with set of vertices Q0 and set of arrows Q1, a representation of Q assigns a vector space Vi to each vertex and a linear map V(α): V(s(α)) → V(t(α)) to each arrow α, where s(α), t(α) are, respectively, the starting and the ending vertices of α. Given an element d ∈ ℕQ0, the set of representations of Q with dim Vi = d(i) for each i has a vector space structure.

It is naturally endowed with an action of the algebraic group ∏i∈ Q0 GL(d(i)) by simultaneous base change. Such action induces one on the ring of functions. The ones which are invariants up to a character of the group are called semi-invariants. They form a ring whose structure reflects representation-theoretical properties of the quiver.

Definitions

Let Q = (Q0,Q1,s,t) be a quiver. Consider a dimension vector d, that is an element in ℕQ0. The set of d-dimensional representations is given by

 \operatorname{Rep}(Q,\mathbf{d}):=\{V\in \operatorname{Rep}(Q) : V_i = \mathbf{d}(i)\}

Once fixed bases for each vector space Vi this can be identified with the vector space

\bigoplus_{\alpha\in Q_1} \operatorname{Hom}_k(k^{\mathbf{d}(s(\alpha))}, k^{\mathbf{d}(t(\alpha))})

Such affine variety is endowed with an action of the algebraic group GL(d) := ∏i∈ Q0 GL(d(i)) by simultaneous base change on each vertex:


\begin{array}{ccc}
GL(\mathbf{d}) \times \operatorname{Rep}(Q,\mathbf{d}) & \longrightarrow & \operatorname{Rep}(Q,\mathbf{d})\\
\Big((g_i), (V_i, V(\alpha))\Big) & \longmapsto & (V_i,g_{t(\alpha)}\cdot V(\alpha)\cdot g_{s(\alpha)}^{-1} )
\end{array}

By definition two modules M,N ∈ Rep(Q,d) are isomorphic if and only if their GL(d)-orbits coincide.

We have an induces action on the coordinate ring k[Rep(Q,d)] by defining:


\begin{array}{ccc}
GL(\mathbf{d}) \times k[\operatorname{Rep}(Q,\mathbf{d})] & \longrightarrow & k[\operatorname{Rep}(Q,\mathbf{d})]\\
(g, f) & \longmapsto & g\cdot f(-):=f(g^{-1}. -)
\end{array}

Polynomial invariants

An element fk[Rep(Q,d)] is called an invariant (with respect to GL(d)) if gf = f for any g ∈ GL(d). The set of invariants

I(Q,\mathbf{d}):=k[\operatorname{Rep}(Q,\mathbf{d})]^{GL(\mathbf{d})}

is in general a subalgebra of k[Rep(Q,d)].

Example

Consider the 1-loop quiver Q:

For d = (n) the representation space is End(kn) and the action of GL(n) is given by usual conjugation. The invariant ring is

I(Q,\mathbf{d})=k[c_1,\ldots,c_n]

where the cis are defined, for any A ∈ End(kn), as the coefficients of the characteristic polynomial

\det(A-t \mathbb{I})=t^n-c_1(A)t^{n-1}+\cdots+(-1)^n c_n(A)

Semi-invariants

In case Q has neither loops nor cycles the variety k[Rep(Q,d)] has a unique closed orbit corresponding to the unique d-dimensional semi-simple representation, therefore any invariant function is constant.

Elements which are invariants with respect to the subgroup SL(d) := ∏{i ∈ Q0} SL(d(i)) form a ring, SI(Q,d), with a richer structure called ring of semi-invariants. It decomposes as

SI(Q,\mathbf{d})=\bigoplus_{\sigma\in \mathbb{Z}^{Q_0}} SI(Q,\mathbf{d})_{\sigma}

where

SI(Q,\mathbf{d})_{\sigma}:= \{f\in k[\operatorname{Rep}(Q,\mathbf{d})] : g\cdot f = \prod_{i\in Q_0}\det(g_i)^{\sigma_i} f, \forall g\in GL(\mathbf{d})\}.

A function belonging to SI(Q,d)σ is called semi-invariant of weight σ.

Example

Consider the quiver Q:

1 \xrightarrow{\ \ \alpha\ } 2

Fix d = (n,n). In this case k[Rep(Q,(n,n))] is congruent to the set of square matrices of size n: M(n). The function defined, for any BM(n), as detu(B(α)) is a semi-invariant of weight (u,−u) in fact

(g_1,g_2)\cdot {\det}^u (B) = {\det}^u(g_2^{-1}B g_1)= {\det}^u(g_1) {\det}^{-u}(g_2) {\det}^u(B)

The ring of semi-invariants equals the polynomial ring generated by det, i.e.

\mathsf{SI}(Q,\mathbf{d})=k[\det]

Characterization of representation type through semi-invariant theory

For quivers of finite representation-type, that is to say Dynkin quivers, the vector space k[Rep(Q,d)] admits an open dense orbit. In other words, it is a prehomogenous vector space. Sato and Kimura described the ring of semi-invariants in such case.

Sato–Kimura theorem

Let Q be a Dynkin quiver, d a dimension vector. Let ∑ be the set of weights σ such that there exists fσ ∈ SI(Q,d)σ non-zero and irreducible. Then the following properties hold true.

i) For every weight σ we have dimk SI(Q,d)σ ≤ 1.

ii) All weights in ∑ are linearly independent over ℚ.

iii) SI(Q,d) is the polynomial ring generated by the fσ's, σ ∈ ∑.

Furthermore, we have an interpretation for the generators of this polynomial algebra. Let O be the open orbit, then k[Rep(Q,d)] \ O = Z1 ∪ ... ∪ Zt where each Zi is closed and irreducible. We can assume that the Zis are arranged in increasing order with respect to the codimension so that the first l have codimension one and Zi is the zero-set of the irreducible polynomial f1, then SI(Q,d) = k[f1, ..., fl].

Example

In the example above the action of GL(n,n) has an open orbit on M(n) consisting of invertible matrices. Then we immediately recover SI(Q,(n,n)) = k[det].

Skowronski–Weyman provided a geometric characterization of the class of tame quivers (i.e. Dynkin and Euclidean quivers) in terms of semi-invariants.

Skowronski–Weyman theorem

Let Q be a finite connected quiver. The following are equivalent:

i) Q is either a Dynkin quiver or an Euclidean quiver.

ii) For each dimension vector d, the algebra SI(Q,d) is complete intersection.

iii) For each dimension vector d, the algebra SI(Q,d) is either a polynomial algebra or a hypersurface.

Example

Consider the Euclidean quiver Q:

Pick the dimension vector d = (1,1,1,1,2). An element Vk[Rep(Q,d)] can be identified with a 4-ple (A1, A2, A3, A4) of matrices in M(1,2). Call Di,j the function defined on each V as det(Ai,Aj). Such functions generate the ring of semi-invariants:

SI(Q,\mathbf{d})=\frac{k[D_{1,2},D_{3,4},D_{1,4},D_{2,3},D_{1,3},D_{2,4}]}{D_{1,2}D_{3,4}+D_{1,4}D_{2,3}-D_{1,3}D_{2,4}}

References

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