Ground-state of fractional and integral quantum Hall systems at ≤ 1 and it excitations

Abstract

Many-body variational ground-state wave function of two-dimensional electron system (2DES), localized in the main strip (MS)Lx × Ly of the finite width Lx=2 π m 0 (and the periodic boundary condition (PBC) imposed along x-direction), is presented at the fractional and the integral filling factors =1/m for two different ion backgrounds: microscopical uniform ion background (UIB) and classical ion jellium background (IJB); 0 is the magnetic length, m=2+1 and =0, 1, 2,.... It is shown that the ground-state and the lowest excited-state can correspond to partial crystal-like correlation order among N electrons of the main region (MR) Lx × Ly; then the study of 2DES of N electrons within MR is exactly reduced to the treatment of 2DES of N=N Lx/Lx electrons localized within MS, with PBC along x. The ground-state manifests the broken symmetry liquid-crystal state with 2DES density that is periodic along the y- direction, with the period Lx/m, and independent of x. For IJB, at m=3, 5, the ground-state has essentially lower energy per electron than the Laughlin, uniform liquid, ground-state (the Laughlin model uses IJB); the same holds at m=1. Obtained compound exciton and compound spin-exciton states show finite excitation gaps. The excited compound electron (hole) is composed, within MS, from m strongly correlated quasielectrons (quasiholes) of the charge e/m (-e/m. Quantized Hall conductance σH=e2/(2 m π ) is obtained. The theory is in good agreement with experiments.

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