Abstract
In the absence of spin-orbit coupling, the conventional dogma of Anderson localization asserts that all states localize in two dimensions, with a glaring exception: the quantum Hall plateau transition (QHPT). In that case, the localization length diverges and interference-induced quantum-critical spatial fluctuations appear at all length scales. Normally QHPT states occur only at isolated energies; accessing them therefore requires fine-tuning of the electron density or magnetic field. In this paper we show that QHPT states can be realized throughout an energy continuum, i.e. as an "energy stack" of critical states wherein each state in the stack exhibits QHPT phenomenology. The stacking occurs without fine-tuning at the surface of a class AIII topological phase, where it is protected by U(1) and (anomalous) chiral or time-reversal symmetries. Spectrum-wide criticality is diagnosed by comparing numerics to universal results for the longitudinal Landauer conductance and wave function multifractality at the QHPT. Results are obtained from an effective 2D surface field theory and from a bulk 3D lattice model. We demonstrate that the stacking of quantum-critical QHPT states is a robust phenomenon that occurs for AIII topological phases with both odd and even winding numbers. The latter conclusion may have important implications for the still poorly-understood logarithmic conformal field theory believed to describe the QHPT.
Highlights
Noninteracting topological quantum phases of matter feature robust gapless edge or surface states [1,2,3]. These states are protected from Anderson localization [4,5,6], defying the central dogma of conventional localization physics according to which all states localize in one dimension, as do most states in two dimensions [7]
The conductivity fitted from this large Lx data is plotted versus energy in Fig. 4(e); we find values in close vicinity to σðxQ;xHPTÞ [Eq (15)] for small E and conductivities increasing with energy for E ≳ 0.3ħv=ξ
While the inverse participation ratio (IPR) is of the same order as for the class AIII WZNW model, the localizing behavior is clearly observed in the resistance data in Fig. 7(c) probing larger length scales
Summary
Noninteracting topological quantum phases of matter feature robust gapless edge or surface states [1,2,3]. If Zirnbauer’s proposal is correct, our numerical results suggest that both the zero- and finite-energy states of the class AIII bulk topological phase with the special winding number ν 1⁄4 4 are governed by the same conformal field theory. In this scenario, the energy perturbation serves only to fine-tune the Abelian disorder strength to the correct value so as to achieve QHPT criticality. At least this proposal should be falsifiable using the class AIII surface state theory, which is a relatively well understood LCFT (a Wess-Zumino-Novikov-Witten model [23,25,26,27,28])
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