Exotic Bilayer Crystals in a Strong Magnetic Field

TL;DR

This paper theoretically predicts three distinct exotic bilayer crystal phases in strong magnetic fields, revealing complex correlated structures that depend on interlayer separation and quantum well width, enriching the understanding of bilayer electron systems.

Contribution

It introduces three novel crystal structures—TIAF, CS, and BG—that are stabilized at different interlayer distances, expanding the known phases of bilayer electron systems.

Findings

Predicted TIAF, CS, and BG crystal phases at various interlayer separations.

All crystals are strongly correlated composite fermion crystals, not just Hartree-Fock crystals.

Provides insight into experimental bilayer insulators and phase transitions.

Abstract

Electron bilayers in a strong magnetic field exhibit insulating behavior for a wide range of interlayer separation $d$ for total Landau level fillings $\nu\leq 1/2$, which has been interpreted in terms of a pinned crystal. We study theoretically the competition between many strongly correlated liquid and crystal states and obtain the phase diagram as a function of quantum well width and $d$ for several filling factors of interest. We predict that three crystal structures can be realized: (a) At small $d$, the Triangular Ising AntiFerromagnetic (TIAF) crystal is stabilized in which the particles overall form a single-layer like triangular crystal while satisfying the condition that no nearest-neighbor triangle has all three particles in the same layer. (b) At intermediate $d$, a Correlated Square (CS) crystal is stabilized, in which particles in each layer form a square lattice, with the particles in one layer located directly across the centers of the squares of the other. (c) At large $d$, we find a Bilayer Graphene (BG) crystal in which the A and B sites of the graphene lattice lie in different layers. All crystals that we predict are strongly correlated crystals of composite fermions; a theory incorporating only electron Hartree-Fock crystals does not find any crystals besides the `trivial' ones occurring at large interlayer separations for total filling factor $\nu\leq1/3$ (when layers are uncorrelated and each layer is in the long familiar single-layer crystal phase). The TIAF, CS and BG crystals come in several varieties, with different flavors of composite fermions and different interlayer correlations. The appearance of these exotic crystal phases adds to the richness of the physics of electron bilayers in a strong magnetic field, and also provides insight into experimentally observed bilayer insulator as well as transitions within the insulating part of the phase diagram.