Composite boson theory of Hall crystals and their transitions to Wigner crystals
Abstract
We consider the crystallization of a two-dimensional electron system in a perpendicular magnetic field using composite boson theory. There are three possible states to consider: the Hall liquid, the Wigner crystal, and the Hall crystal (a state with both broken translation symmetry and a quantized Hall response). Within composite boson theory, these states map onto a superconductor, a Mott insulator, and a supersolid of composite bosons respectively. We show that when a = 1 Hall liquid has a sufficiently soft roton, there is a first order transition to a triangular lattice Hall crystal. If we continue to decrease the roton mass, there is a continuous transition from the Hall crystal to a Wigner crystal. When the Hall crystal exhibits the integer quantum Hall effect, this transition is described by a free Dirac fermion and, at the critical point, the coupling to the phonons of the crystal is irrelevant, in the renormalization group sense. We extend this analysis to fractional = 1/m Hall liquids. There, due to kinetic frustration arising from flux attachment, honeycomb lattice Hall crystals are preferred over triangular ones at intermediate interaction strength.
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