Massive Dirac Fermion on the Surface of a Magnetically Doped Topological Insulator

Massive Dirac Fermion on the Surface of a Magnetically Doped Topological Insulator

In addition to a bulk energy gap, topological insulators accommodate a conducting, linearly dispersed Dirac surface state. This state is predicted to become massive if time reversal symmetry is broken, and to become insulating if the Fermi energy is positioned inside both the surface and bulk gaps....

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2010-08, Vol.329 (5992), p.659-662
Hauptverfasser: Chen, Y.L, Chu, J.-H, Analytis, J.G, Liu, Z.K, Igarashi, K, Kuo, H.-H, Qi, X.L, Mo, S.K, Moore, R.G, Lu, D.H, Hashimoto, M, Sasagawa, T, Zhang, S.C, Fisher, I.R, Hussain, Z, Shen, Z.X
Format: Artikel
Sprache:eng
Schlagworte:
Condensed matter
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Dopants
Doping
Electron density of states and band structure of crystalline solids
Electron states
Electronic publishing
Electronic structure
Energy gap
Exact sciences and technology
Fermi surfaces
Fermions
Gaps
Insulators
Materials
Materials science
Mathematical surfaces
Other inorganic compounds
Photons
Physics
Quantum physics
Semiconductor doping
Symmetry
Topology
Transport phenomena
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Zusammenfassung:In addition to a bulk energy gap, topological insulators accommodate a conducting, linearly dispersed Dirac surface state. This state is predicted to become massive if time reversal symmetry is broken, and to become insulating if the Fermi energy is positioned inside both the surface and bulk gaps. We introduced magnetic dopants into the three-dimensional topological insulator dibismuth triselenide (Bi₂Se₃) to break the time reversal symmetry and further position the Fermi energy inside the gaps by simultaneous magnetic and charge doping. The resulting insulating massive Dirac fermion state, which we observed by angle-resolved photoemission, paves the way for studying a range of topological phenomena relevant to both condensed matter and particle physics.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.1189924