Magnetic Dirac semimetal state of (Mn,Ge)Bi2Te4

Abstract

For quantum electronics, the possibility to finely tune the properties of magnetic topological insulators (TIs) is a key issue. We studied solid solutions between two isostructural Z2 TIs, magnetic MnBi2Te4 and nonmagnetic GeBi2Te4, with Z2 invariants of 1;000 and 1;001, respectively. For high-quality, large mixed crystals of GexMn1-xBi2Te4, we observed linear x-dependent magnetic properties, composition-independent pairwise exchange interactions along with an easy magnetization axis. The bulk band gap gradually decreases to zero for x from 0 to 0.4, before reopening for x>0.6, evidencing topological phase transitions (TPTs) between topologically nontrivial phases and the semimetal state. The TPTs are driven purely by the variation of orbital contributions. By tracing the x-dependent 6p contribution to the states near the fundamental gap, the effective spin-orbit coupling variation is extracted. As x varies, the maximum of this contribution switches from the valence to the conduction band, thereby driving two TPTs. The gapless state observed at x=0.42 closely resembles a Dirac semimetal above the Neel temperature and shows a magnetic gap below, which is clearly visible in raw photoemission data. The observed behavior of the GexMn1-xBi2Te4 system thereby demonstrates an ability to precisely control topological and magnetic properties of TIs.