Electronic structures and photoemission spectroscopy

ARPES study of the epitaxially grown topological crystalline insulator SnTe(111)

Journal of Electron Spectroscopy and Related Phenomena Elsevier 219 (2017) 35-40

Authors:

Yi Zhang, Zhongkai Liu, Bo Zhou, Yeongkwan Kim, Lexian Yang, Hyejin Ryu, Choongyu Hwang, Yulin Chen, Zahid Hussain, Zhi-Xun Shen, Sung-Kwan Mo

Spectroscopic evidence for the gapless electronic structure in bulk ZrTe5

Journal of Electron Spectroscopy and Related Phenomena Elsevier 219 (2017) 45-52

Authors:

L Shen, MX Wang, SC Sun, J Jiang, X Xu, T Zhang, QH Zhang, YY Lv, SH Yao, YB Chen, MH Lu, YF Chen, C Felser, BH Yan, ZK Liu, LX Yang, YL Chen

Observation of nodal line in non-symmorphic topological semimetal InBi

New Journal of Physics IOP Publishing 19:065007 (2017) 1-8

Authors:

Sandy A Ekahana, S-C Wu, J Jiang, K Okawa, Dharmalingam Prabhakaran, C-C Hwang, S-K Mo, T Sasagawa, C Felser, B Yan, Z Liu, Yulin Chen

Abstract:

Topological nodal semimetal (TNS), characterized by its touching conduction and valence bands, is a newly discovered state of quantum matter which exhibits various exotic physical phenomena. Recently, a new type of TNS called topological nodal line semimetal (TNLS) is predicted where its conduction and valence band form a degenerate one-dimension line which is further protected by its crystal symmetry. In this work, we systematically investigated the bulk and surface electronic structure of the non-symmorphic, TNLS in InBi (which is also a type II Dirac semimetal) with strong spin-orbit coupling by using angle resolved photoemission spectroscopy. By tracking the crossing points of the bulk bands at the Brillouin zone boundary, we discovered the nodal-line feature along the kz direction, in agreement with the ab initio calculations and confirmed it to be a new compound in the TNLS family. Our discovery provides a new material platform for the study of these exotic topological quantum phases and paves the way for possible future applications.

Emergence of Dirac-like bands in the monolayer limit of epitaxial Ge films on Au(1 1 1)

2D Materials Institute of Physics 4:3 (2017) 031005

Authors:

Niels BM Schröter, Watson, Liam B Duffy, M Hoesch, Yulin Chen, Thorsten Hesjedal, TK Kim

Abstract:

After the discovery of Dirac fermions in graphene, it has become a natural question to ask whether it is possible to realize Dirac fermions in other two-dimensional (2D) materials as well. In this work, we report the discovery of multiple Dirac-like electronic bands in ultrathin Ge films grown on Au(1 1 1) by angle-resolved photoelectron spectroscopy. By tuning the thickness of the films, we are able to observe the evolution of their electronic structure when passing through the monolayer limit. Our discovery may signify the synthesis of germanene, a 2D honeycomb structure made of Ge, which is a promising platform for exploring exotic topological phenomena and enabling potential applications.

Nontrivial Berry phase and type-II Dirac transport in the layered material PdTe2

Physical Review B American Physical Society (APS) 96:4 (2017) 041201

Authors:

Fucong Fei, Xiangyan Bo, Rui Wang, Bin Wu, Juan Jiang, Dongzhi Fu, Ming Gao, Hao Zheng, Yulin Chen, Xuefeng Wang, Haijun Bu, Fengqi Song, Xiangang Wan, Baigeng Wang, Guanghou Wang