Electronic structures and photoemission spectroscopy

Massive Dirac fermion observed in lanthanide-doped topological insulator thin films

Scientific Reports Nature Publishing Group 5:1 (2015) 15767

Authors:

SE Harrison, Liam J Collins-McIntyre, Piet Schönherr, A Vailionis, V Srot, PA van Aken, AJ Kellock, A Pushp, SSP Parkin, JS Harris, B Zhou, YL Chen, Thorsten Hesjedal

Abstract:

The breaking of time reversal symmetry (TRS) in three-dimensional (3D) topological insulators (TIs) and thus the opening of a ‘Dirac-mass gap’ in the linearly dispersed Dirac surface state, is a prerequisite for unlocking exotic physical states. Introducing ferromagnetic long-range order by transition metal doping has been shown to break TRS. Here, we present the study of lanthanide (Ln) doped Bi2Te3, where the magnetic doping with high-moment lanthanides promises large energy gaps. Using molecular beam epitaxy, single-crystalline, rhombohedral thin films with Ln concentrations of up to ~35%, substituting on Bi sites, were achieved for Dy, Gd and Ho doping. Angle-resolved photoemission spectroscopy shows the characteristic Dirac cone for Gd and Ho doping. In contrast, for Dy doping above a critical doping concentration, a gap opening is observed via the decreased spectral intensity at the Dirac point, indicating a topological quantum phase transition persisting up to room-temperature.

Weyl semimetal phase in the non-centrosymmetric compound TaAs

Nature Physics 11:9 (2015) 728-732

Authors:

LX Yang, ZK Liu, Y Sun, H Peng, HF Yang, T Zhang, B Zhou, Y Zhang, YF Guo, M Rahn, D Prabhakaran, Z Hussain, SK Mo, C Felser, B Yan, YL Chen

Abstract:

Three-dimensional (3D) topological Weyl semimetals (TWSs) represent a state of quantum matter with unusual electronic structures that resemble both a '3D graphene' and a topological insulator. Their electronic structure displays pairs of Weyl points (through which the electronic bands disperse linearly along all three momentum directions) connected by topological surface states, forming a unique ark-like Fermi surface (FS). Each Weyl point is chiral and contains half the degrees of freedom of a Dirac point, and can be viewed as a magnetic monopole in momentum space. By performing angle-resolved photoemission spectroscopy on the non-centrosymmetric compound TaAs, here we report its complete band structure, including the unique Fermi-arc FS and linear bulk band dispersion across the Weyl points, in agreement with the theoretical calculations. This discovery not only confirms TaAs as a 3D TWS, but also provides an ideal platform for realizing exotic physical phenomena (for example, negative magnetoresistance, chiral magnetic effects and the quantum anomalous Hall effect) which may also lead to novel future applications.

Weyl semimetal phase in the non-centrosymmetric compound TaAs

Nature Physics Springer Nature 11:9 (2015) 728-732

Authors:

LX Yang, ZK Liu, Y Sun, H Peng, HF Yang, T Zhang, B Zhou, Y Zhang, YF Guo, M Rahn, D Prabhakaran, Z Hussain, S-K Mo, C Felser, B Yan, YL Chen

van Hove Singularity Enhanced Photochemical Reactivity of Twisted Bilayer Graphene

Nano Letters American Chemical Society (ACS) 15:8 (2015) 5585-5589

Authors:

Lei Liao, Huan Wang, Han Peng, Jianbo Yin, Ai Leen Koh, Yulin Chen, Qin Xie, Hailin Peng, Zhongfan Liu

Extremely large magnetoresistance and ultrahigh mobility in the topological Weyl semimetal candidate NbP

Nature Physics Springer Nature 11:8 (2015) 645-649

Authors:

Chandra Shekhar, Ajaya K Nayak, Yan Sun, Marcus Schmidt, Michael Nicklas, Inge Leermakers, Uli Zeitler, Yurii Skourski, Jochen Wosnitza, Zhongkai Liu, Yulin Chen, Walter Schnelle, Horst Borrmann, Yuri Grin, Claudia Felser, Binghai Yan