Condensed Matter Theory

Size constraints on a Majorana beam-splitter interferometer: Majorana coupling and surface-bulk scattering

Physical Review B American Physical Society 97:11 (2018) 115424

Authors:

Henrik Schou Røising, Steven Simon

Abstract:

Topological insulator surfaces in proximity to superconductors have been proposed as a way to produce Majorana fermions in condensed matter physics. One of the simplest proposed experiments with such a system is Majorana interferometry. Here we consider two possibly conflicting constraints on the size of such an interferometer. Coupling of a Majorana mode from the edge (the arms) of the interferometer to vortices in the center of the device sets a lower bound on the size of the device. On the other hand, scattering to the usually imperfectly insulating bulk sets an upper bound. From estimates of experimental parameters, we find that typical samples may have no size window in which the Majorana interferometer can operate, implying that a new generation of more highly insulating samples must be explored.

Twist-induced crossover from 2D to 3D turbulence in active nematics

(2018)

Authors:

Tyler N Shendruk, Kristian Thijssen, Julia M Yeomans, Amin Doostmohammadi

Low-temperature transport in out-of-equilibrium XXZ chains

Journal of Statistical Mechanics Theory and Experiment IOP Publishing 2018:3 (2018) 033104

Authors:

Bruno Bertini, Lorenzo Piroli

Shape dependent phoretic propulsion of slender active particles

Physical Review Fluids American Physical Society (APS) 3:3 (2018) 033101

Authors:

Y Ibrahim, R Golestanian, TB Liverpool

Topological Entanglement Entropy of Fracton Stabilizer Codes

Physical Review B American Physical Society 97 (2018) 125101

Authors:

H Ma, AT Schmitz, Parameswaran, M Hermele, R Nandkishore

Abstract:

Entanglement entropy provides a powerful characterization of two-dimensional gapped topological phases of quantum matter, intimately tied to their description by topological quantum field theories (TQFTs). Fracton topological orders are three-dimensional gapped topologically ordered states of matter that lack a TQFT description. We show that three-dimensional fracton phases are nevertheless characterized, at least partially, by universal structure in the entanglement entropy of their ground-state wave functions. We explicitly compute the entanglement entropy for two archetypal fracton models, the “X-cube model” and “Haah's code,” and demonstrate the existence of a nonlocal contribution that scales linearly in subsystem size. We show via Schrieffer-Wolff transformations that this piece of the entanglement entropy of fracton models is robust against arbitrary local perturbations of the Hamiltonian. Finally, we argue that these results may be extended to characterize localization-protected fracton topological order in excited states of disordered fracton models.