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Creation of Helical Dirac Fermions by Interfacing Two Gapped Systems of Ordinary Fermions

Topological insulators (TIs) are a unique class of materials characterized by a surface (edge) Dirac cone state of helical Dirac fermions in the middle of bulk (surface) gap. When the thickness (width) of TIs is reduced, however, interaction between the surface (edge) states will open a gap removing the Dirac cone. Using density function theory calculation, we demonstrate the creation of helical Dirac fermions from interfacing two gapped TI films, a single bilayer Bi grown on a single quintuple layer Bi2Se3 or Bi2Te3. The theoretical prediction is directly confirmed by experiment. We further show that the extrinsic helical Dirac fermions consists of predominantly Bi bilayer states, which are created by a giant Rashba effect due to interfacial charge transfer. Our findings provide a promising new method to create novel TI materials by interface engineering.

preprint2013arXivOpen access
Z. F. WangMeng-Yu YaoWenmei MingLin MiaoFengfeng ZhuCanhua LiuC. L. GaoDong QianJin-Feng JiaFeng Liu
cond-mat.mes-hallcond-mat.mtrl-sci
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Z. F. WangMeng-Yu YaoWenmei MingLin MiaoFengfeng ZhuCanhua LiuC. L. GaoDong QianJin-Feng JiaFeng Liu

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