Abstract
We propose a new approach to studying electrical networks interpreting the Ohm law as the operator which solves certain local Yang–Baxter equation. Using this operator and the medial graph of the electrical network we define a vertex integrable statistical model and its boundary partition function. This gives an equivalent description of electrical networks. We show that, in the important case of an electrical network on the standard graph introduced in [Curtis E B et al 1998 Linear Algebr. Appl. 283 115–50], the response matrix of an electrical network, its most important feature, and the boundary partition function of our statistical model can be recovered from each other. Defining the electrical varieties in the usual way we compare them to the theory of the Lusztig varieties developed in [Berenstein A et al 1996 Adv. Math. 122 49–149]. In our picture the former turns out to be a deformation of the later. Our results should be compared to the earlier work started in [Lam T and Pylyavskyy P 2015 Algebr. Number Theory 9 1401–18] on the connection between the Lusztig varieties and the electrical varieties. There the authors introduced a one-parameter family of Lie groups which are deformations of the unipotent group. For the value of the parameter equal to 1 the group in the family acts on the set of response matrices and is related to the symplectic group. Using the data of electrical networks we construct a representation of the group in this family which corresponds to the value of the parameter −1 in the symplectic group and show that our boundary partition functions belong to it. Remarkably this representation has been studied before in the work on six vertex statistical models and the representations of the Temperley–Lieb algebra.
Highlights
The set of toric charts labelled by reduced words for the longest permutation coming out of the factorization of a unipotent matrix into a product of the Jacobi matrices
The transition maps between the charts correspond to the local “YangBaxter” mutations and a particular solution to the tetrahedron Zamolodchikov equation defines the formulas for these transition maps
Suppose we are given a pair (Γ, γ), where Γ is a connected graph, a subset of its vertices is labelled as the boundary vertices or nodes, the rest are forming the set of the interior vertices and γ is a function from the set E(Γ) of edges of Γ to real numbers. It defines an electrical network with the conductivity function γ on Γ if γ takes positive values
Summary
The definition of electrical variety has appeared already in [13], [11], and [3], so we just recall it here. Suppose we are given a pair (Γ, γ), where Γ is a connected graph, a subset of its vertices is labelled as the boundary vertices or nodes, the rest are forming the set of the interior vertices and γ is a function from the set E(Γ) of edges of Γ to real numbers. It defines an electrical network with the conductivity function γ on Γ if γ takes positive values. The matrix MR does not change under star-triangular mutations of the pair (Γ, γ) and it defines a function on T with values in matrices
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