Condensed Matter Theory

Fractionalizing glide reflections in two-dimensional Z2 topologically ordered phases

Physical Review B 94:12 (2016)

Authors:

S Lee, M Hermele, SA Parameswaran

Abstract:

© 2016 American Physical Society. We study the fractionalization of space group symmetries in two-dimensional topologically ordered phases. Specifically, we focus on Z2-fractionalized phases in two dimensions whose deconfined topological excitations transform trivially under translational symmetries but projectively under glide reflections, whose quantum numbers are hence fractionalized. We accomplish this by generalizing the dichotomy between even and odd gauge theories to incorporate additional symmetries inherent to nonsymmorphic crystals. We show that the resulting fractionalization of point group quantum numbers can be detected in numerical studies of ground state wave functions. We illustrate these ideas using a microscopic model of a system of bosons at integer unit cell filling on a lattice with space group p4g that can be mapped to a half-magnetization plateau for an S=1/2 spin system on the Shastry-Sutherland lattice.

The macroscopic pancake bounce

(2016)

Authors:

Jonas Andersen Bro, Kasper Sternberg Brogaard Jensen, Alex Nygaard Larsen, Julia M Yeomans, Tina Hecksher

Efficient representation of fully many-body localized systems using tensor networks

(2016)

Authors:

Thorsten B Wahl, Arijeet Pal, Steven H Simon

Topological defects on the lattice: I. The Ising model

JOURNAL OF PHYSICS A-MATHEMATICAL AND THEORETICAL 49:35 (2016) ARTN 354001

Authors:

D Aasen, RSK Mong, P Fendley

Hydrodynamics of micro-swimmers in films

Journal of Fluid Mechanics Cambridge University Press 806 (2016) 35-70

Authors:

Julia M Yeomans, Tyler N Shendruk, Arnoldus JTM Mathijssen, Amin Doostmohammadi

Abstract:

One of the principal mechanisms by which surfaces and interfaces affect microbial life is by perturbing the hydrodynamic flows generated by swimming. By summing a recursive series of image systems we derive a numerically tractable approximation to the threedimensional flow fields of a Stokeslet (point force) within a viscous film between a parallel no-slip surface and no-shear interface and, from this Green's function, we compute the flows produced by a force- and torque-free micro-swimmer. We also extend the exact solution of Liron and Mochon (1976) to the film geometry, which demonstrates that the image series gives a satisfactory approximation to the swimmer flow fields if the film is sufficiently thick compared to the swimmer size, and we derive the swimmer flows in the thin-film limit. Concentrating on the thick film case, we find that the dipole moment induces a bias towards swimmer accumulation at the no-slip wall rather than the waterair interface, but that higher-order multipole moments can oppose this. Based on the analytic predictions we propose an experimental method to find the multipole coefficient that induces circular swimming trajectories, allowing one to analytically determine the swimmer's three-dimensional position under a microscope.