Luis Seabra scite author profile

The Heisenberg antiferromagnet on a two-dimensional triangular lattice is a paradigmatic problem in frustrated magnetism. Even in the classical limit S → ∞, its properties are far from simple. The "120 degree" ground state favoured by the frustrated antiferromagnetic interactions contains a hidden chiral symmetry, and supports two distinct types of excitation. And famously, three distinct phases, including a collinear one-third magnetisation plateau, are stabilised by thermal fluctuations in applied magnetic field. The questions of symmetry-breaking raised by this model are deep and subtle, and after more than thirty years of study, many of the details of its phase diagram remain surprisingly obscure. In this paper we use modern Monte Carlo simulation techniques to determine the finite-temperature phase diagram of the classical Heisenberg antiferromagnet on a triangular lattice in applied magnetic field. At low to intermediate values of magnetic field, we find evidence for a continuous phase transition from the paramagnet into the collinear one-third magnetisation plateau, belonging to the three-state Potts universality class. We also find evidence for conventional Berezinskii-Kosterlitz-Thouless transitions from the one-third magnetisation plateau into the canted "Y-state", and into the 2:1 canted phase found at high fields. However, the phase transition from the paramagnet into the 2:1 canted phase, while continuous, does not appear to fall into any conventional universality class. We argue that this, like the chiral phase transition discussed in zero field, deserves further study as an interesting example of a finite-temperature phase transition with compound order-parameter symmetry. We comment on the relevance of these results for experiments on magnetic materials with a triangular lattice.

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From fractionally charged solitons to Majorana bound states in a one-dimensional interacting model

Sticlet

Seabra

Pollmann

et al. 2014

Phys. Rev. B

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We consider one-dimensional topological insulators hosting fractionally charged midgap states in the presence and absence of induced superconductivity pairing. Under the protection of a discrete symmetry, relating positive and negative energy states, the solitonic midgap states remain pinned at zero energy when superconducting correlations are induced by proximity effect. When the superconducting pairing dominates the initial insulating gap, Majorana fermion phases develop for a class of insulators. As a concrete example, we study the Creutz model with induced s-wave superconductivity and repulsive Hubbard-type interactions. For a finite wire, without interactions, the solitonic modes originating from the nonsuperconducting model survive at zero energy, revealing a fourfold-degenerate ground state. However, interactions break the aforementioned discrete symmetry and completely remove this degeneracy, thereby producing a unique ground state which is characterized by a topological bulk invariant with respect to the product of fermion parity and bond inversion. In contrast, the Majorana edge modes are globally robust to interactions. Moreover, the parameter range for which a topological Majorana phase is stabilized expands when increasing the repulsive Hubbard interaction. The topological phase diagram of the interacting model is obtained using a combination of mean-field theory and density matrix renormalization group techniques.

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Phase diagram of the spin-1/2J₁-J₂-J₃Heisenberg model on the square lattice with ferromagneticJ₁

Sindzingre

Seabra

Shannon

et al. 2009

J. Phys.: Conf. Ser.

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Luis Seabra

Phase diagram of the classical Heisenberg antiferromagnet on a triangular lattice in an applied magnetic field

From fractionally charged solitons to Majorana bound states in a one-dimensional interacting model

Phase diagram of the spin-1/2J₁-J₂-J₃Heisenberg model on the square lattice with ferromagneticJ₁

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About

Luis Seabra

Phase diagram of the classical Heisenberg antiferromagnet on a triangular lattice in an applied magnetic field

From fractionally charged solitons to Majorana bound states in a one-dimensional interacting model

Phase diagram of the spin-1/2J1-J2-J3Heisenberg model on the square lattice with ferromagneticJ1

Contact Info

Product

Resources

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Phase diagram of the spin-1/2J₁-J₂-J₃Heisenberg model on the square lattice with ferromagneticJ₁