Steve Simon

Excitations in the Higher Lattice Gauge Theory Model for Topological Phases II: The (2+1)-Dimensional Case

(2022)

Authors:

Joe Huxford, Steven H Simon

Excitations in the Higher Lattice Gauge Theory Model for Topological Phases I: Overview

(2022)

Authors:

Joe Huxford, Steven H Simon

Quantifying information scrambling via Classical Shadow Tomography on Programmable Quantum Simulators

(2022)

Authors:

Max McGinley, Sebastian Leontica, Samuel J Garratt, Jovan Jovanovic, Steven H Simon

Excitonic fractional quantum Hall hierarchy in moire heterostructures

PHYSICAL REVIEW B 105:23 (2022) ARTN 235121

Authors:

Yves H Kwan, Yichen Hu, Steven H Simon, SA Parameswaran

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

Physical Review X American Physical Society 11:4 (2021) 041063

Authors:

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

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 Kekulé spiral' (IKS) order, spontaneously breaks both the emergent valley-charge conservation and moiré translation symmetries, but preserves a modified translation symmetry 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.