Frank Göhmann scite author profile

The description of solids at a microscopic level is complex, involving the interaction of a huge number of its constituents, such as ions or electrons. It is impossible to solve the corresponding many-body problems analytically or numerically, although much insight can be gained from the analysis of simplified models. An important example is the Hubbard model, which describes interacting electrons in narrow energy bands, and which has been applied to problems as diverse as high-Tc superconductivity, band magnetism, and the metal-insulator transition. This 2005 book presents a coherent, self-contained account of the exact solution of the Hubbard model in one dimension. The early chapters will be accessible to beginning graduate students with a basic knowledge of quantum mechanics and statistical mechanics. The later chapters address more advanced topics, and are intended as a guide for researchers to some of the more topical results in the field of integrable models.

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Integral representations for correlation functions of theXXZchain at finite temperature

Göhmann

Klümper

Seel

2004

J. Phys. A: Math. Gen.

188

347

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Short-distance thermal correlations in the XXZ chain

et al. 2008

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Recent studies have revealed much of the mathematical structure of the static correlation functions of the XXZ chain. Here we use the results of those studies in order to work out explicit examples of short-distance correlation functions in the infinite chain. We compute two-point functions ranging over 2, 3 and 4 lattice sites as functions of the temperature and the magnetic field for various anisotropies in the massless regime −1 < ∆ < 1. It turns out that the new formulae are numerically efficient and allow us to obtain the correlations functions over the full parameter range with arbitrary precision. † The results of this and of the following section are valid for all ∆ > −1. Later on in sections 4 and 5 we restrict ourselves to the massless regime −1 < ∆ < 1.

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Thermal form factors of theXXZchain and the large-distance asymptotics of its temperature dependent correlation functions

Dugave¹,

Göhmann²,

Kozłowski³

2013

J. Stat. Mech.

172

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We derive expressions for the form factors of the quantum transfer matrix of the spin-1 2 XXZ chain which are suitable for taking the infinite Trotter number limit. These form factors determine the finitely many amplitudes in the leading asymptotics of the finite-temperature correlation functions of the model. We consider form-factor expansions of the longitudinal and transversal two-point functions. Remarkably, the formulae for the amplitudes are in both cases of the same form. We also explain how to adapt our formulae to the description of ground state correlation functions of the finite chain. The usefulness of our novel formulae is demonstrated by working out explicit results in the high-and low-temperature limits. We obtain, in particular, the large-distance asymptotics of the longitudinal twopoint functions for small temperatures by summing up the asymptotically most relevant terms in the form factor expansion of a generating function of the longitudinal correlation functions. As expected the leading term in the expansion of the corresponding two-point functions is in accordance with conformal field theory predictions. Here it is obtained for the first time by a direct calculation.

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On the physical part of the factorized correlation functions of the XXZ chain

Boos¹,

Göhmann²

2009

J. Phys. A: Math. Theor.

171

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It was recently shown by Jimbo, Miwa and Smirnov that the correlation functions of a generalized XXZ chain associated with an inhomogeneous six-vertex model with disorder parameter α and with arbitrary inhomogeneities on the horizontal lines factorize and can all be expressed in terms of only two functions ρ and ω. Here we approach the description of the same correlation functions and, in particular, of the function ω from a different direction. We start from a novel multiple integral representation for the density matrix of a finite chain segment of length m in the presence of a disorder field α. We explicitly factorize the integrals for m = 2. Based on this we present an alternative description of the function ω in terms of the solutions of certain linear and nonlinear integral equations. We then prove directly that the two definitions of ω describe the same function. The definition in the work of Jimbo, Miwa and Smirnov was crucial for the proof of the factorization. The definition given here together with the known description of ρ in terms of the solutions of nonlinear integral equations is useful for performing e.g. the Trotter limit in the finite temperature case, or for obtaining numerical results for the correlation functions at short distances. We also address the issue of the construction of an exponential form of the density matrix for finite α.

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Frank Göhmann

The One-Dimensional Hubbard Model

Integral representations for correlation functions of theXXZchain at finite temperature

Short-distance thermal correlations in the XXZ chain

Thermal form factors of theXXZchain and the large-distance asymptotics of its temperature dependent correlation functions

On the physical part of the factorized correlation functions of the XXZ chain

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