Abstract
We develop an efficient method to compute the torus partition function of the six-vertex model exactly for finite lattice size. The method is based on the algebro-geometric approach to the resolution of Bethe ansatz equations initiated in a previous work, and on further ingredients introduced in the present paper. The latter include rational Q-system, primary decomposition, algebraic extension and Galois theory. Using this approach, we probe new structures in the solution space of the Bethe ansatz equations which enable us to boost the efficiency of the computation. As an application, we study the zeros of the partition function in a partial thermodynamic limit of M × N tori with N ≫ M. We observe that for N → ∞ the zeros accumulate on some curves and give a numerical method to generate the curves of accumulation points.
Highlights
Computing partition functions of two-dimensional lattice models is one of the central problems in statistical mechanics
We develop an efficient method to compute the torus partition function of the six-vertex model exactly for finite lattice size
The eigenvalues of the transfer matrix obtained in this way are only formal, since they are written in terms of Bethe roots, which are solutions of Bethe ansatz equations (BAE)
Summary
Computing partition functions of two-dimensional lattice models is one of the central problems in statistical mechanics. When the lattice model is integrable, one can often compute the partition function exactly. We consider the torus partition function of the six-vertex model at its isotropic point, with lattice size M × N. This is a well-known integrable model which is equivalent to the Heisenberg XXX spin chain [1]. The partition function can be written in terms of the eigenvalues of the transfer matrix To compute the partition function explicitly, we need to solve the BAE and find all physical solutions and plug in the eigenvalues of the transfer matrix. What is usually not stressed in the literature is that it is a highly non-trivial task to find all the solutions of the BAE, even numerically
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