Guido Jüttner scite author profile

We present a novel treatment of finite temperature properties of the onedimensional Hubbard model. Our approach is based on a Trotter-Suzuki mapping utilizing Shastry's classical model and a subsequent investigation of the quantum transfer matrix. We derive non-linear integral equations for three auxiliary functions which have a clear physical interpretation of elementary excitations of spin type and charge excitations in lower and upper Hubbard bands. This allows for a transparent analytical study of certain limiting cases as well as for precise numerical investigations. We present data for the specific heat, magnetic and charge susceptibilities for various particle densities and coupling strengths U . The structure exposed by these curves is discussed in terms of the elementary charge and spin excitations. Special emphasis is placed on the study of the low-temperature behavior within our ab initio approach confirming the scaling predictions by Tomonaga-Luttinger liquid theory. In addition we make contact with the "dressed energy" formalism established for the analysis of ground state properties. *

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From fusion hierarchy to excited state TBA

Jüttner

Klümper

Suzuki

1998

Nuclear Physics B

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Functional relations among the fusion hierarchy of quantum transfer matrices give a novel derivation of the TBA equations, namely without string hypothesis. This is demonstrated for two important models of 1D highly correlated electron systems, the supersymmetric t − J model and the supersymmetric extended Hubbard model. As a consequence, "the excited state TBA" equations, which characterize correlation lengths, are explicitly derived for the t − J model. To the authors' knowledge, this is the first explicit derivation of excited state TBA equations for 1D lattice electron systems.

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Exact thermodynamics and Luttinger liquid properties of the integrable t-J model

Jüttner¹,

Klümper²,

Suzuki³

1997

Nuclear Physics B

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A Trotter-Suzuki mapping is used to calculate the finite-temperature properties of the one-dimensional supersymmetric t − J model. This approach allows for the exact calculation of various thermodynamical properties by means of the quantum transfer matrix (QTM). The free energy and other interesting quantities are obtained such as the specific heat and compressibility. For the largest eigenvalue of the QTM leading to the free energy a set of just two non-linear integral equations is presented. These equations are studied analytically and numerically for different particle densities and temperatures. The structure of the specific heat is discussed in terms of the elementary charge as well as spin excitations. Special emphasis is placed on the study of the low-temperature behavior confirming scaling predictions by conformal field theory and Luttinger liquid theory. To our knowledge this is the first complete investigation of a strongly correlated electron system on a lattice at finite temperature. *

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Exact calculation of thermodynamical quantities of the integrable t – J model

Jüttner

Klümper

1997

Europhys. Lett.

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The specific heat and the compressibility for the integrable t–J model are calculated showing Luttinger liquid behavior for low temperatures. A Trotter-Suzuki mapping and the quantum transfer matrix approach are utilized. Using an algebraic Bethe ansatz, this method permits the exact calculation of the free energy and related quantities. A set of just two non-linear integral equations determining these quantities is studied for various particle densities and temperatures. The structure of the specific heat is discussed in terms of the elementary charge as well as spin excitations.

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Completeness of “good” Bethe ansatz solutions of a quantum-group-invariant Heisenberg model

Jüttner

Karowski

1994

Nuclear Physics B

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The sl q (2)-quantum group invariant spin 1/2 XXZ-Heisenberg model with open boundary conditions is investigated by means of the Bethe ansatz. As is well known, quantum groups for q equal to a root of unity possess a finite number of "good" representations with non-zero q-dimension and "bad" ones with vanishing q-dimension. Correspondingly, the state space of an invariant Heisenberg chain decomposes into "good" and "bad" states. A "good" state may be described by a path of only "good" representations. It is shown that the "good" states are given by all "good" Bethe ansatz solutions with roots restricted to the first periodicity strip, i.e. only positive parity strings (in the language of Takahashi) are allowed. Applying Bethe's string counting technique completeness of the "good" Bethe states is proven, i.e. the same number of states is found as the number of all restricted path's on the sl q (2)-Bratteli diagram. It is the first time that a "completeness" proof for an anisotropic quantum invariant reduced Heisenberg model is performed.

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Guido Jüttner

The Hubbard chain at finite temperatures: ab initio calculations of Tomonaga-Luttinger liquid properties

From fusion hierarchy to excited state TBA

Exact thermodynamics and Luttinger liquid properties of the integrable t-J model

Exact calculation of thermodynamical quantities of the integrable t – J model

Completeness of “good” Bethe ansatz solutions of a quantum-group-invariant Heisenberg model

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