Condensed Matter Theory

Fractional Chern insulators and the W ∞ algebra

Physical Review B - Condensed Matter and Materials Physics 85:24 (2012)

Authors:

SA Parameswaran, R Roy, SL Sondhi

Abstract:

A set of recent results indicates that fractionally filled bands of Chern insulators in two dimensions support fractional quantum Hall states analogous to those found in fractionally filled Landau levels. We provide an understanding of these results by examining the algebra of Chern band projected density operators. We find that this algebra closes at long wavelengths and for constant Berry curvature, whereupon it is isomorphic to the W ∞ algebra of lowest Landau level projected densities first identified by Girvin, MacDonald, and Platzman. For Hamiltonians projected to the Chern band this provides a route to replicating lowest Landau level physics on the lattice. © 2012 American Physical Society.

Fractional quantum hall effect of lattice bosons near commensurate flux

Physical Review Letters 108:25 (2012)

Authors:

L Hormozi, G Möller, SH Simon

Abstract:

We study interacting bosons on a lattice in a magnetic field. When the number of flux quanta per plaquette is close to a rational fraction, the low-energy physics is mapped to a multispecies continuum model: bosons in the lowest Landau level where each boson is given an internal degree of freedom, or pseudospin. We find that the interaction potential between the bosons involves terms that do not conserve pseudospin, corresponding to umklapp processes, which in some cases can also be seen as BCS-type pairing terms. We argue that in experimentally realistic regimes for bosonic atoms in optical lattices with synthetic magnetic fields, these terms are crucial for determining the nature of allowed ground states. In particular, we show numerically that certain paired wave functions related to the Moore-Read Pfaffian state are stabilized by these terms, whereas certain other wave functions can be destabilized when umklapp processes become strong. © 2012 American Physical Society.

Fractional Chern insulators and the W∞ algebra

Physical Review B American Physical Society (APS) 85:24 (2012) 241308

Authors:

SA Parameswaran, R Roy, SL Sondhi

Typology for quantum Hall liquids

Physical Review B American Physical Society (APS) 85:24 (2012) 241307

Authors:

SA Parameswaran, SA Kivelson, EH Rezayi, SH Simon, SL Sondhi, BZ Spivak

DNA cruciform arms nucleate through a correlated but non-synchronous cooperative mechanism

ArXiv 1206.2636 (2012)

Authors:

Christian Matek, Thomas E Ouldridge, Adam Levy, Jonathan PK Doye, Ard A Louis

Abstract:

Inverted repeat (IR) sequences in DNA can form non-canonical cruciform structures to relieve torsional stress. We use Monte Carlo simulations of a recently developed coarse-grained model of DNA to demonstrate that the nucleation of a cruciform can proceed through a cooperative mechanism. Firstly, a twist-induced denaturation bubble must diffuse so that its midpoint is near the centre of symmetry of the IR sequence. Secondly, bubble fluctuations must be large enough to allow one of the arms to form a small number of hairpin bonds. Once the first arm is partially formed, the second arm can rapidly grow to a similar size. Because bubbles can twist back on themselves, they need considerably fewer bases to resolve torsional stress than the final cruciform state does. The initially stabilised cruciform therefore continues to grow, which typically proceeds synchronously, reminiscent of the S-type mechanism of cruciform formation. By using umbrella sampling techniques we calculate, for different temperatures and superhelical densities, the free energy as a function of the number of bonds in each cruciform along the correlated but non-synchronous nucleation pathways we observed in direct simulations.