Transfer matrices

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updates: 6 December 2011

Lattice models and Transfer matrices

Let $A$ be a vector space with basis ${f_{μ}}$ and let $V$ be a vector space with basis ${e_{α}}$ .

The Boltzmann weights are the matrix entries

of an operator $L (u) : A \otimes V \to A \otimes V$ .
The monodromy matrix is $T (u) : A \otimes V^{\otimes N} \to A \otimes V^{\otimes N} given by T (u) = L_{01} (u) L_{02} (u) \dots L_{0 N} (u) .$
The transfer matrix is $𝒯 (u) : V^{\otimes N} \to V^{\otimes N} given by 𝒯 (u) = {Tr}_{A} T (u) .$
The Hamiltonian is $H = (const) {\frac{d}{d u} log 𝒯 (u) |}_{u = const} + (const) .$
The partition function on an $N \times M$ lattice is $Z (u) = {Tr}_{V^{\otimes N}} 𝒯 (u) .$

As operators on $A \otimes A \otimes V$ , $R_{12} (u, v) L_{13} (v) L_{23} (u) = L_{23} (u) L_{13} (v) R_{12} (u, v)$ and this implies that, as operators on $A \otimes A \otimes V^{\otimes N}$ ,

R_{12} (u, v) T_{13} (v) T_{23} (u) = T_{23} (u) T_{13} (v) R_{12} (u, v)

(1.1)

Multiplying on the left by

{R_{12} (u, v)}^{- 1}

and taking

{Tr}_{A \otimes A}

gives

𝒯 (u) 𝒯 (v) = 𝒯 (v) 𝒯 (u) .

Remark: In many applications $R (u, v) = R (u - v)$ and the quantum Yang-Baxter equation (QYBE) gives $R_{12} (u - v) R_{13} (v) R_{23} (u) = R_{23} (u) R_{13} (v) R_{12} (u - v),$ with $L (u) = R (u)$ gives (1.1).

Notes and References

This page is based on section 5.2 of [dG]. The formula ??? appears as ??? in [TF] who quote [Bax].

References

[Bax] R. Baxter, One-dimensional anisotropic Heisenberg chain, Ann. Phys. 70 (1972), 323-337.

[dG] J. de Gier, Random Tilings and Solvable Lattice Models, Ph.D Thesis, University of Amsterdam, 1998.

[TF] L.A. Takhtajan and L.D. Faddeev, The quantum method of the inverse problem and the Heisenberg XYZ model, Russian Math Surveys 34 5 (1979), 11-68.

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