Matthias Peschke scite author profile

We solve the quantum-mechanical antiferromagnetic Heisenberg model with spins positioned on vertices of the truncated icosahedron using the density-matrix renormalization group (DMRG). This describes magnetic properties of the undoped C_{60}60 fullerene at half filling in the limit of strong on-site interaction UU. We calculate the ground state and correlation functions for all possible distances, the lowest singlet and triplet excited states, as well as thermodynamic properties, namely the specific heat and spin susceptibility. We find that unlike smaller C_{20}20 or C_{32}32 that are solvable by exact diagonalization, the lowest excited state is a triplet rather than a singlet, indicating a reduced frustration due to the presence of many hexagon faces and the separation of the pentagonal faces, similar to what is found for the truncated tetrahedron. This implies that frustration may be tuneable within the fullerenes by changing their size. The spin-spin correlations are much stronger along the hexagon bonds and exponentially decrease with distance, so that the molecule is large enough not to be correlated across its whole extent. The specific heat shows a high-temperature peak and a low-temperature shoulder reminiscent of the kagomé lattice, while the spin susceptibility shows a single broad peak and is very close to the one of C_{20}20.

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Frustrated quantum magnetism in the Kondo lattice on the zigzag ladder

Peschke

Rausch

Potthoff

2018

Phys. Rev. B

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The interplay between Kondo effect, indirect magnetic interaction and geometrical frustration is studied in the Kondo lattice on the one-dimensional zigzag ladder. Using the density-matrix renormalization group (DMRG), the ground state and various short-and long-range spin-and densitycorrelation functions are calculated for the model at half-filling as a function of the antiferromagnetic Kondo interaction down to J = 0.3t where t is the nearest-neighbor hopping on the zigzag ladder. Geometrical frustration is shown to lead to at least two critical points: Starting from the strong-J limit, where almost local Kondo screening dominates and where the system is a nonmagnetic Kondo insulator, antiferromagnetic correlations between nearest-neighbor and next-nearest-neighbor local spins become stronger and stronger, until at J dim c ≈ 0.89t frustration is alleviated by a spontaneous breaking of translational symmetry and a corresponding transition to a dimerized state. This is characterized by antiferromagnetic correlations along the legs and by alternating antiferro-and ferromagnetic correlations on the rungs of the ladder. A mechanism of partial Kondo screening that has been suggested for the Kondo lattice on the two-dimensional triangular lattice is not realized in the one-dimensional case. Furthermore, within the symmetry-broken dimerized state, there is a magnetic transition to a 90 • quantum spin spiral with quasi-long-range order at J mag c ≈ 0.84t. The quantum-critical point is characterized by a closure of the spin gap (with decreasing J) and a divergence of the spin-correlation length and of the spin-structure factor S(q) at wave vector q = π/2. This is opposed to the model on the one-dimensional bipartite chain, which is known to have a finite spin gap for all J > 0 at half-filling. arXiv:1709.05642v2 [cond-mat.str-el] 12 Mar 2018 As the spin gap, the charge gap ∆ C is of the order of J in the strong-J regime. It decreases with decreasing J but stays finite at and below J mag c . This is consistent with our expectation that the systems is an insulator for arbitrary J > 0 at half-filling.

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Topological phases arising from attractive interaction and pair hopping in the extended Hubbard model

Rausch

Peschke

2020

New J. Phys.

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The extended Hubbard model with an attractive density–density interaction, positive pair hopping, or both, is shown to host topological phases, with a doubly degenerate entanglement spectrum and interacting edge spins. This constitutes a novel instance of topological order which emerges from interactions. When the interaction terms combine in a charge-SU(2) symmetric fashion, a novel partially polarized pseudospin phase appears, in which the topological features of the spin degrees of freedom coexist with long-range η-wave superconductivity. Thus, our system provides an example of an interplay between spontaneous symmetry breaking and symmetry-protected topological order that leads to novel and unexpected properties.

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