Collapse of Spin-Splitting in the Quantum Hall Effect

Abstract

It is known experimentally that at not very large filling factors the quantum Hall conductivity peaks corresponding to the same Landau level number N and two different spin orientations are well separated. These peaks occur at half-integer filling factors = 2 N + 1/2 and = 2 N + 3/2 so that the distance between them δ is unity. As increases δ shrinks. Near certain N = Nc two peaks abruptly merge into a single peak at = 2N + 1. We argue that this collapse of the spin-splitting at low magnetic fields is attributed to the disorder-induced destruction of the exchange enhancement of the electron g-factor. We use the mean-field approach to show that in the limit of zero Zeeman energy δ experiences a second-order phase transition as a function of the magnetic field. We give explicit expressions for Nc in terms of a sample's parameters. For example, we predict that for high-mobility heterostructures Nc = 0.9 d n5/6 ni-1/3, where d is the spacer width, n is the density of the two-dimensional electron gas, and ni is the two-dimensional density of randomly situated remote donors.

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