Observation of a transition from a topologically ordered to a spontaneously broken symmetry phase

For the fast rotating quasi-two-dimensional dipolar fermions in the quantum Hall regime, the interaction between two dipoles breaks the rotational symmetry when the dipole moment has in-plane components that can be tuned by an external field. Assuming that all the dipoles are polarized in the same direction, we perform the numerical diagonalization for finite size systems on a torus. We find that while ν = 1/3 Laughlin state is stable in the lowest Landau level (LLL), it is not stable in the first Landau level (1LL); instead, the most stable Laughlin state in the 1LL is the ν = 2 + 1/5 Laughlin state. These FQH states are robust against moderate introduction of anisotropy, but large anisotropy induces a transition into a compressible phase in which all the particles are attracted and form a bound state. We show that such phase transitions can be detected by the intrinsic geometrical properties of the ground states alone. The anisotropy and the phase transition are systematically studied with the generalized pseudopotentials and characterized by the intrinsic metric, the wave function overlap and the nematic order parameter. We also propose simple model Hamiltonians for this physical system in the LLL and 1LL respectively.

Section: Introductionmentioning

confidence: 81%

Phase transition and intrinsic metric of dipolar fermions in the quantum Hall regime

Yang

et al. 2018

“…The closing and re-opening of the energy gap with density was interpreted as a spin transition in the ν = 5/2 FQHS 25 . In another experiment, pressure has drastically altered the ground state at ν = 5/2 near κ 2 from a FQHS to a stripe phase 32 . Since in these experiments an in-situ tuning of the density was not possible, subtle changes in sample properties are virtually impossible to detect.…”

Section: Introductionmentioning

confidence: 99%

Observation of an anomalous density-dependent energy gap of the ν=5/2 fractional quantum Hall state in the low-density regime

Samkharadze¹,

Ro²,

Pfeiffer³

et al. 2017

Self Cite

We have studied the ν = 5/2 fractional quantum Hall state in a density-tunable sample at extremely low electron densities. For the densities accessed in our experiment, the Landau level mixing parameter κ spans the 2.52 < κ < 2.82 range. In the vicinity of 5.8 × 10 10 cm −2 or κ = 2.6 an anomalously large change in the density dependence of the energy gap is observed. Possible origins of such an anomaly are discussed, including a topological phase transition in the ν = 5/2 fractional quantum Hall state.

“…In addition to these theoretical studies, there is good experimental evidence that a modest in-plane field drives the isotropic incompressible state observed in GaAs at ν = 5/2 into a phase with highly anisotropic transport [43][44][45][46][47] , and a recent experiment has even induced a phase transition into an anisotropic phase by tuning isotropic pressure 48 . However, the nature of the resulting anisotropic phase and its connection to the MR state is not fully understood.…”

mentioning

confidence: 99%

Anisotropy-driven transition from the Moore-Read state to quantum Hall stripes

Zhu¹,

Sodemann²,

Fu³

2017

We investigate the nature of the quantum Hall liquid in a half-filled second Landau level (n = 1) as a function of band mass anisotropy using numerical exact diagonalization (ED) and density matrix renormalization group (DMRG) methods. We find increasing the mass anisotropy induces a quantum phase transition from the MooreRead state to a charge density wave state. By analyzing the energy spectrum, guiding center structure factors and by adding weak pinning potentials, we show that this charge density wave is a uni-directional quantum Hall stripe, which has a periodicity of a few magnetic lengths and survives in the thermodynamic limit. We find smooth profiles for the guiding center occupation function that reveal the strong coupling nature of the array of chiral Luttinger liquids residing at the stripe edges.