Condensed Matter Theory

Kekulé spiral order at all nonzero integer fillings in twisted bilayer graphene

Physical Review X American Physical Society

Authors:

Yves H Kwan, Glenn Wagner, Tomohiro Soejima, Michael P Zaletel, Steven H Simon, Siddharth A Parameswaran, Nick Bultinck

Abstract:

We study magic angle graphene in the presence of both strain and particle-hole symmetry breaking due to non-local inter-layer tunneling. We perform a self-consistent Hartree-Fock study that incorporates these effects alongside realistic interaction and substrate potentials, and explore a comprehensive set of competing orders including those that break translational symmetry at arbitrary wavevectors. We find that at all non-zero integer fillings very small strains, comparable to those measured in scanning tunneling experiments, stabilize a fundamentally new type of time-reversal symmetric and spatially non-uniform order. This order, which we dub the 'incommensurate Kekul\'e spiral' (IKS) order, spontaneously breaks both the emergent valley-charge conservation and moir\'e translation symmetries, but preserves a modified translation symmetry $\hat{T}'$ -- which simultaneously shifts the spatial coordinates and rotates the $U(1)$ angle which characterizes the spontaneous inter-valley coherence. We discuss the phenomenological and microscopic properties of this order. We argue that our findings are consistent with all experimental observations reported so far, suggesting a unified explanation of the global phase diagram in terms of the IKS order.

Lattice supersymmetry and order-disorder coexistence in the tricritical Ising model

Physical Review Letters American Physical Society

Authors:

Paul Fendley, E O'Brien

Linear response and exact hydrodynamic projections in Lindblad equations with decoupled Bogoliubov hierarchies

SciPost Physics SciPost

Authors:

Fabian Essler, Patrik Penc

Local measures enable COVID-19 containment with fewer restrictions due to cooperative effects

Authors:

Philip Bittihn, Lukas Hupe, Jonas Isensee, Ramin Golestanian

Many-body delocalisation as symmetry breaking

Phys. Rev. Lett. 127 026802-026802

Authors:

Sj Garratt, Jt Chalker

Abstract:

We present a framework in which the transition between a many-body localised (MBL) phase and an ergodic one is symmetry breaking. We consider random Floquet spin chains, expressing their averaged spectral form factor (SFF) as a function of time in terms of a transfer matrix that acts in the space direction. The SFF is determined by the leading eigenvalues of this transfer matrix. In the MBL phase the leading eigenvalue is unique, as in a symmetry-unbroken phase, while in the ergodic phase and at late times the leading eigenvalues are asymptotically degenerate, as in a system with degenerate symmetry-breaking phases. We identify the broken symmetry of the transfer matrix, introduce a local order parameter for the transition, and show that the associated correlation functions are long-ranged only in the ergodic phase.