Smearing of the quantum anomalous Hall effect due to statistical fluctuations of magnetic dopants

Abstract

Quantum anomalous Hall effect (QAH) is induced by substitution of a certain portion, x, of Bi atoms in a BiTe-based insulating parent compound by magnetic ions (Cr or V). We find the density of in-gap states, N(E), emerging as a result of statistic fluctuations of the composition, x, in the vicinity of the transition point, where the average gap, Eg, passes through zero. Local gap follows the fluctuations of x. Using the instanton approach, we show that, near the gap edges, the tails are exponential, ln N(E) -(Eg-|E|), and the tail states are due to small gap reduction. Our main finding is that, even when the smearing magnitude exceeds the gap-width, there exists are semi-hard gap around zero energy, where ln N(E) -Eg/|E| (ln Eg/|E|). The states responsible for N(E) originate from local gap reversals within narrow rings. The consequence of semi-hard gap is the Arrhenius, rather than variable-range hopping, temperature dependence of the diagonal conductivity at low temperatures.