Abstract
The quantum anomalous Hall effect (QAHE) is a fundamental quantum transport phenomenon that manifests as a quantized transverse conductance in response to a longitudinally applied electric field in the absence of an external magnetic field, and it promises to have immense application potential in future dissipationless quantum electronics. Here, we present a novel kinetic pathway to realize the QAHE at high temperatures by n-p codoping of three-dimensional topological insulators. We provide a proof-of-principle numerical demonstration of this approach using vanadium-iodine (V-I) codoped Sb_{2}Te_{3} and demonstrate that, strikingly, even at low concentrations of ∼2% V and ∼1% I, the system exhibits a quantized Hall conductance, the telltale hallmark of QAHE, at temperatures of at least ∼50 K, which is 3 orders of magnitude higher than the typical temperatures at which it has been realized to date. The underlying physical factor enabling this dramatic improvement is tied to the largely preserved intrinsic band gap of the host system upon compensated n-p codoping. The proposed approach is conceptually general and may shed new light in experimental realization of high-temperature QAHE.
Highlights
The quantum anomalous Hall effect (QAHE) is a fundamental quantum transport phenomenon that manifests as a quantized transverse conductance in response to a longitudinally applied electric field in the absence of an external magnetic field, and promises to have immense application potentials in future dissipation-less quantum electronics
In the pioneering work predicting the QAHE in magnetic topological insulators (TIs) [12], the estimated Curie temperature is high, but neither the bulk nor the thin film band gap was obtained from firstprinciples calculations, making it impossible to critically assess the likely QAHE observation temperature
We found that the V-V magnetic coupling is ferromagnetic for all the V-V separation considered, strongly indicating a preponderance toward a diluted ferromagnetism (Fig. 1d) - the magnetic coupling is defined as the energy difference between ferromagnetic and anti-ferromagnetic configurations
Summary
The quantum anomalous Hall effect (QAHE) is a fundamental quantum transport phenomenon that manifests as a quantized transverse conductance in response to a longitudinally applied electric field in the absence of an external magnetic field, and promises to have immense application potentials in future dissipation-less quantum electronics. There are two crucial energy scales, the actual band gap of the magnetic TI thin films and the ferromagnetic Curie temperature, with the smaller of the two defining the upper limit of the QAHE observation temperature.
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