Abstract
The evolution of extended states of two-dimensional electron gas with white-noise randomness and field is numerically investigated by using the Anderson model on square lattices. Focusing on the lowest Landau band we establish an anti-levitation scenario of the extended states: As either the disorder strength W increases or the magnetic field strength B decreases, the energies of the extended states move below the Landau energies pertaining to a clean system. Moreover, for strong enough disorder, there is a disorder-dependent critical magnetic field Bc(W) below which there are no extended states at all. A general phase diagram in the W-1/B plane is suggested with a line separating domains of localized and delocalized states. © 2014 American Physical Society.
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CITATION STYLE
Wang, C., Avishai, Y., Meir, Y., & Wang, X. R. (2014). Anti-levitation in integer quantum Hall systems. Physical Review B - Condensed Matter and Materials Physics, 89(4). https://doi.org/10.1103/PhysRevB.89.045314
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