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論文

Fabrication of a novel magnetic topological heterostructure and temperature evolution of its massive Dirac cone

平原 徹*; Otrokov, M. M.*; 佐々木 泰佑*; 角田 一樹*; 友弘 雄太*; 日下 翔太郎*; 奥山 裕磨*; 一ノ倉 聖*; 小林 正起*; 竹田 幸治; et al.

Nature Communications (Internet), 11, p.4821_1 - 4821_8, 2020/09

 被引用回数:1 パーセンタイル:100(Multidisciplinary Sciences)

We fabricate a novel magnetic topological heterostructure Mn$$_{4}$$Bi$$_{2}$$Te$$_{7}$$/Bi$$_{2}$$Te$$_{3}$$ where multiple magnetic layers are inserted into the topmost quintuple layer of the original topological insulator Bi$$_{2}$$Te$$_{3}$$. A massive Dirac cone (DC) with a gap of 40-75 meV at 16 K is observed. By tracing the temperature evolution, this gap is shown to gradually decrease with increasing temperature and a blunt transition from a massive to a massless DC occurs around 200-250 K. Magnetic measurements show that there are two distinct Mn components in the system that corresponds to the two heterostructures; MnBi$$_{2}$$Te$$_{4}$$/Bi$$_{2}$$Te$$_{3}$$ is paramagnetic at 6 K while Mn$$_{4}$$Bi$$_{2}$$Te$$_{7}$$/Bi$$_{2}$$Te$$_{3}$$ is ferromagnetic with a negative hysteresis (critical temperature 20 K). This novel heterostructure is potentially important for future device applications.

論文

Nature of the Dirac gap modulation and surface magnetic interaction in axion antiferromagnetic topological insulator MnBi$$_{2}$$Te$$_{4}$$

Shikin, A. M.*; Estyunin, D. A.*; Klimovskikh, I. I.*; Filnov, S. O.*; Kumar, S.*; Schwier, E. F.*; 宮本 幸治*; 奥田 太一*; 木村 昭夫*; 黒田 健太*; et al.

Scientific Reports (Internet), 10, p.13226_1 - 13226_13, 2020/08

 被引用回数:0 パーセンタイル:100(Multidisciplinary Sciences)

Modification of the gap at the Dirac point (DP) in axion antiferromagnetic topological insulator MnBi$$_{2}$$Te$$_{4}$$ and its electronic and spin structure have been studied by angle- and spin-resolved photoemission spectroscopy (ARPES) under laser excitation at various temperatures, light polarizations and photon energies. We have distinguished both large and reduced gaps at the DP in the ARPES dispersions, which remain open above the N$'{e}$el temperature of $$T_textrm{N}$$ = 24.5 K. We propose that the gap above $$T_textrm{N}$$ remains open due to a short-range magnetic field generated by chiral spin fluctuations. Spin-resolved ARPES, XMCD and circular dichroism ARPES measurements show a surface ferromagnetic ordering for the large gap sample and apparently significantly reduced effective magnetic moment for the reduced gap sample.

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