Topologically Nontrivial Phase-Change Compound GeSb2Te4.
Munisa NurmamatKazuaki OkamotoSiyuan ZhuTatiana V MenshchikovaIgor P RusinovVladislav O KorostelevKoji MiyamotoTaichi OkudaTakeo MiyashitaXiaoxiao WangYukiaki IshidaKazuki SumidaEike F SchwierMao YeZiya S AlievMahammad B BabanlyImamaddin R AmiraslanovEvgueni V ChulkovKonstantin A KokhOleg E TereshchenkoKenya ShimadaShik ShinAkio KimuraPublished in: ACS nano (2020)
Chalcogenide phase-change materials show strikingly contrasting optical and electrical properties, which has led to their extensive implementation in various memory devices. By performing spin-, time-, and angle-resolved photoemission spectroscopy combined with the first-principles calculation, we report the experimental results that the crystalline phase of GeSb2Te4 is topologically nontrivial in the vicinity of the Dirac semimetal phase. The resulting linearly dispersive bulk Dirac-like bands that cross the Fermi level and are thus responsible for conductivity in the stable crystalline phase of GeSb2Te4 can be viewed as a 3D analogue of graphene. Our finding provides us with the possibility of realizing inertia-free Dirac currents in phase-change materials.