Jan Borchmann scite author profile

In this paper we study the phase diagram of a disordered, spin-orbit coupled superconductor with s-wave or d + id-wave pairing symmetry in symmetry class D. We analyze the topological phase transitions by applying three different methods which include a disorder averaged entanglement entropy, a disorder averaged real-space Chern number, and an evaluation of the momentum space Chern number in a disorder averaged effective model. We find evidence for a disorder-induced topological state. While in the clean limit there is a single phase transition from a trivial phase with a Chern number C = 4 to a topological phase with C = 1, in the disordered system there is an intermediate phase with C = 3. The phase transition from the trivial C = 4 phase into the intermediate phase with C = 3 is seen in the real-space calculation of the Chern number. In spite of this, this phase transition is not detectable in the entanglement entropy. A second phase transition from the disorder induced C = 3 into the C = 1 phase is seen in all three quantities.

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Entanglement spectrum as a probe for the topology of a spin-orbit-coupled superconductor

Borchmann

Farrell

Matsuura

et al. 2014

Phys. Rev. B

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The classification of electron systems according to their topology has been at the forefront of condensed matter research in recent years. It has been found that systems of the same symmetry, previously thought of as equivalent, may in fact be distinguished by their topological properties. Moreover, the non-trivial topology found in some insulators and superconductors has profound physical implications that can be observed experimentally and can potentially be used for applications. However, characterizing a system's topology is not always a simple task, even for a theoretical model. When translation and other symmetries are present in a quadratic model the topological invariants are readily defined and easily calculated in a variety of symmetry classes. However, once interactions or disorder come into play the task becomes difficult, and in many cases prohibitively so. The goal of this paper is to test whether the entanglement entropy and entanglement spectrum bare signatures of the system's topology. Using quadratic models of superconductors we demonstrate that these entanglement properties are sensitive to changes in topology. arXiv:1407.5980v2 [cond-mat.str-el]

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Quantum oscillations in Weyl semimetals: A surface theory approach

Borchmann

Pereg-Barnea

2017

Phys. Rev. B

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We develop an effective surface theory for the surface states of a Weyl semimetal. This theory includes the peculiar Fermi arc states on the surface as well as leakage of the states from the surface to the bulk. Subjecting the model to a magnetic field perpendicular to the surface results in quantum oscillations. The oscillations are different from the usual ones since they do not involve a closed Fermi surface cross section. It has been shown previously that the Quantum oscillations can be understood semiclassically as resulting from motion of electrons on the surface Fermi arcs as well as tunneling through chiral Landau levels associated with the bulk. In this work we develop an effective surface theory and use it to analyze the quantum oscillation in the semiclassical regime and beyond. Specifically, we show that when a pair of Weyl points are close to each other the surface quantum oscillations acquire a phase offset which originates from the bulk. While the surface states are responsible for a large part of the electron motion, tunneling through the bulk is necessary for completing the orbit. This tunneling makes use of the bulk, zero energy, chiral Landau level in each Weyl node. When the nodes are close in momentum space their chiral levels overlap and a gap at zero energy is formed. This gap causes the phase offset in the surface quantum oscillations.

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Analytic expression for the entanglement entropy of a two-dimensional topological superconductor

Borchmann

Pereg-Barnea

2017

Phys. Rev. B

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We study a model of two dimensional, topological superconductivity on a square lattice. The model contains hopping, spin orbit coupling and a time reversal symmetry breaking Zeeman term. This term, together with the chemical potential act as knobs that induce transitions between trivial and topological superconductivity. As previously found numerically, the transitions are seen in the entanglement entropy as cusps as a function of model parameters. In this work we study the entanglement entropy analytically by keeping only its most important components. Our study is based on the intuition that the number of Fermi surfaces in the system controls the topological invariant. With our approximate expression for the entanglement entropy we are able to extract the divergent entanglement entropy derivative close to the phase transition.

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Microscopic dipole-exchange theory for magnonic crystal arrays of interacting ferromagnetic nanorings

Borchmann

Nguyen

Cottam

2013

Journal of the Korean Physical Society

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Jan Borchmann

Anderson topological superconductor

Entanglement spectrum as a probe for the topology of a spin-orbit-coupled superconductor

Quantum oscillations in Weyl semimetals: A surface theory approach

Analytic expression for the entanglement entropy of a two-dimensional topological superconductor

Microscopic dipole-exchange theory for magnonic crystal arrays of interacting ferromagnetic nanorings

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