Abstract
Recent years have witnessed tremendous success in the discovery of topological states of matter. Particularly, sophisticated theoretical methods in time-reversal-invariant topological phases have been developed, leading to the comprehensive search of crystal database and the prediction of thousands of topological materials. In contrast, the discovery of magnetic topological phases that break time reversal is still limited to several exemplary materials because the coexistence of magnetism and topological electronic band structure is rare in a single compound. To overcome this challenge, we propose an alternative approach to realize the quantum anomalous Hall (QAH) effect, a typical example of magnetic topological phase, via engineering two-dimensional (2D) magnetic van der Waals heterojunctions. Instead of a single magnetic topological material, we search for the combinations of two 2D (typically trivial) magnetic insulator compounds with specific band alignment so that they can together form a type-III broken-gap heterojunction with topologically non-trivial band structure. By combining the data-driven materials search, first-principles calculations, and the symmetry-based analytical models, we identify eight type-III broken-gap heterojunctions consisting of 2D ferromagnetic insulators in the MXY compound family as a set of candidates for the QAH effect. In particular, we directly calculate the topological invariant (Chern number) and chiral edge states in the MnNF/MnNCl heterojunction with ferromagnetic stacking. This work illustrates how data-driven material science can be combined with symmetry-based physical principles to guide the search for heterojunction-based quantum materials hosting the QAH effect and other exotic quantum states in general.
Highlights
The quantum anomalous Hall (QAH) effect[1,2,3], a zero magnetic field manifestation of the integer quantum Hall effect, originates from the exchange interaction between electron spin and magnetism and exhibits quantized Hall resistance and zero longitudinal resistance
Discovery workflow for QAH heterojunctions Despite several recent works[25,26], the search for more QAH materials is still challenging because it requires the coexistence of ferromagnetism and topological band structure, which is rare in a single material
We propose an alternative strategy to realize the QAH effect in 2D magnetic van der Waals (VdW) heterojunctions by combining data-driven discovery of 2D magnetic compounds with a theoretical analysis of topological properties
Summary
The quantum anomalous Hall (QAH) effect[1,2,3], a zero magnetic field manifestation of the integer quantum Hall effect, originates from the exchange interaction between electron spin and magnetism and exhibits quantized Hall resistance and zero longitudinal resistance. Guided by theoretical predictions[8], the QAH effect was experimentally demonstrated in the magnetically (Cr or V) doped (Bi, Sb)2Te39–12. Magnetic doping reduces the spin-orbit coupling (SOC) strength and may drive the system into a trivial phase. It degrades the sample quality by bringing a large amount of disorder scatterings into the system. The critical temperature of the QAH state through the magnetic doping approach is usually below 2 K, an order-ofmagnitude lower than the Curie temperature of these compounds. It is highly desirable to search for new platforms consisting of stoichiometric materials with intrinsic magnetism to realize high temperature QAH state
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