Your search keyword '"Xie Zhuo-Jin"' showing total 7 results

1. Electronic Structure of Transition Metal Dichalcogenides PdTe2 and Cu0.05PdTe2 Superconductors Obtained by Angle-Resolved Photoemission Spectroscopy

Author

Liu, Yan, Zhao, Jian Zhor, Yu, Li, Lin, Cheng Tian, Hu, Cheng, Liu, De Fa, Peng, Ying Ting, Xie, Zhuo Jin, He, Jun Feng, Chen, Chao Yu, Feng, Ya, Yi, He Mian, Liu, Xu, Zhao, Lin, He, Shao Long, Liu, Guo Dong, Dong, Xiao Li, Zhang, Jun, Chen, Chuang Tian, Xu, Zu Yan, Weng, Hongming, Dai, Xi, Fang, Zhong, Zhou, Xingjiang, Liu, Yan, Zhao, Jian Zhor, Yu, Li, Lin, Cheng Tian, Hu, Cheng, Liu, De Fa, Peng, Ying Ting, Xie, Zhuo Jin, He, Jun Feng, Chen, Chao Yu, Feng, Ya, Yi, He Mian, Liu, Xu, Zhao, Lin, He, Shao Long, Liu, Guo Dong, Dong, Xiao Li, Zhang, Jun, Chen, Chuang Tian, Xu, Zu Yan, Weng, Hongming, Dai, Xi, Fang, Zhong, and Zhou, Xingjiang

Abstract

The layered transition metal chalcogenides have been a fertile land in solid state physics for many decades. Various MX2-type transition metal dichalcogenides, such as WTe2, IrTe2, and MoS2, have triggered great attention recently, either for the discovery of novel phenomena or some extreme or exotic physical properties, or for their potential applications. PdTe2 is a superconductor in the class of transition metal dichalcogenides, and superconductivity is enhanced in its Cu-intercalated form, Cu0.05PdTe2. It is important to study the electronic structures of PdTe2 and its intercalated form in order to explore for new phenomena and physical properties and understand the related superconductivity enhancement mechanism. Here we report systematic high resolution angle-resolved photoemission (ARPES) studies on PdTe2 and Cu0.05PdTe2 single crystals, combined with the band structure calculations. We present in detail for the first time the complex multi-band Fermi surface topology and densely-arranged band structure of these compounds. By carefully examining the electronic structures of the two systems, we find that Cu-intercalation in PdTe2 results in electron-doping, which causes the band structure to shift downwards by nearly 16 me V in Cu0.05PdTe2. Our results lay a foundation for further exploration and investigation on PdTe2 and related superconductors. © 2015 Chinese Physical Society and IOP Publishing Ltd.

Published

2015

2. Electronic structure of transition metal dichalcogenides PdTe 2 and Cu 0.05 PdTe 2 superconductors obtained by angle-resolved photoemission spectroscopy

Author

Liu, Yan, primary, Zhao, Jian-Zhou, additional, Yu, Li, additional, Lin, Cheng-Tian, additional, Hu, Cheng, additional, Liu, De-Fa, additional, Peng, Ying-Ying, additional, Xie, Zhuo-Jin, additional, He, Jun-Feng, additional, Chen, Chao-Yu, additional, Feng, Ya, additional, Yi, He-Mian, additional, Liu, Xu, additional, Zhao, Lin, additional, He, Shao-Long, additional, Liu, Guo-Dong, additional, Dong, Xiao-Li, additional, Zhang, Jun, additional, Chen, Chuang-Tian, additional, Xu, Zu-Yan, additional, Weng, Hong-Ming, additional, Dai, Xi, additional, Fang, Zhong, additional, and Zhou, Xing-Jiang, additional

Published

2015

3. Electronic Structure, Irreversibility Line and Magnetoresistance of Cu 0.3 Bi 2 Se 3 Superconductor

Author

Yi, He-Mian, primary, Chen, Chao-Yu, additional, Sun, Xuan, additional, Xie, Zhuo-Jin, additional, Feng, Ya, additional, Liang, Ai-Ji, additional, Peng, Ying-Ying, additional, He, Shao-Long, additional, Zhao, Lin, additional, Liu, Guo-Dong, additional, Dong, Xiao-Li, additional, Zhang, Jun, additional, Chen, Chuang-Tian, additional, Xu, Zu-Yan, additional, Gu, Gen-Da, additional, and Zhou, Xing-Jiang, additional

Published

2015

4. Observation of a Flat Band in Silicene

Author

Feng, Ya, primary, Feng, Bao-Jie, additional, Xie, Zhuo-Jin, additional, Li, Wen-Bin, additional, Liu, Xu, additional, Liu, De-Fa, additional, Zhao, Lin, additional, Chen, Lan, additional, Zhou, Xing-Jiang, additional, and Wu, Ke-Hui, additional

Published

2014

5. Weak Electron-Phonon Coupling and Unusual Electron Scattering of Topological Surface States in Sb(111) by Laser-Based Angle-Resolved Photoemission Spectroscopy

Author

Xie, Zhuo-Jin, primary, He, Shao-Long, additional, Chen, Chao-Yu, additional, Feng, Ya, additional, Yi, He-Mian, additional, Liang, Ai-Ji, additional, Zhao, Lin, additional, Mou, Dai-Xiang, additional, He, Jun-Feng, additional, Peng, Ying-Ying, additional, Liu, Xu, additional, Liu, Yan, additional, Liu, Guo-Dong, additional, Dong, Xiao-Li, additional, Yu, Li, additional, Zhang, Jun, additional, Zhang, Shen-Jin, additional, Wang, Zhi-Min, additional, Zhang, Feng-Feng, additional, Yang, Feng, additional, Peng, Qin-Jun, additional, Wang, Xiao-Yang, additional, Chen, Chuang-Tian, additional, Xu, Zu-Yan, additional, and Zhou, Xing-Jiang, additional

Published

2014

6. Electronic Structure, Irreversibility Line and Magnetoresistance of Cu0.3Bi2Se3 Superconductor.

Author

Yi He-Mian, Chen Chao-Yu, Sun Xuan, Xie Zhuo-Jin, Feng Ya, Liang Ai-Ji, Peng Ying-Ying, He Shao-Long, Zhao Lin, Liu Guo-Dong, Dong Xiao-Li, Zhang Jun, Chen Chuang-Tian, Xu Zu-Yan, Gu Gen-Da, and Zhou Xing-Jiang

Subjects

SUPERCONDUCTORS, PHOTOEMISSION, ELECTRONIC structure, MAGNETORESISTANCE, ELECTRICAL resistivity

Abstract

CuxBi2Se3 is a superconductor that is a potential candidate for topological superconductors. We report our laser-based angle-resolved photoemission measurement on the electronic structure of the CuxBi2Se3 superconductor, and a detailed magneto-resistance measurement in both normal and superconducting states. We find that the topological surface state of the pristine Bi2Se3 topological insulator remains robust after the Cu-intercalation, while the Dirac cone location moves downward due to electron doping. Detailed measurements on the magnetic field-dependence of the resistance in the superconducting state establishes an irreversibility line and gives a value of the upper critical field at zero temperature of ∼4000 Oe for the Cu0.3Bi2Se3 superconductor with a middle point Tc of 1.9K. The relation between the upper critical field Hc2 and temperature T is different from the usual scaling relation found in cuprates and in other kinds of superconductors. Small positive magneto-resistance is observed in Cu0.3Bi2Se3 superconductors up to room temperature. These observations provide useful information for further study of this possible candidate for topological superconductors. [ABSTRACT FROM AUTHOR]

Published

2015

7. Electronic structure of transition metal dichalcogenides PdTe2 and Cu0.05PdTe2 superconductors obtained by angle-resolved photoemission spectroscopy.

Author

Liu Yan, Zhao Jian-Zhou, Yu Li, Lin Cheng-Tian, Hu Cheng, Liu De-Fa, Peng Ying-Ying, Xie Zhuo-Jin, He Jun-Feng, Chen Chao-Yu, Feng Ya, Yi He-Mian, Liu Xu, Zhao Lin, He Shao-Long, Liu Guo-Dong, Dong Xiao-Li, Zhang Jun, Chen Chuang-Tian, and Xu Zu-Yan

Subjects

CHALCOGENIDES, SOLID state physics, PHOTOEMISSION, FERMI surfaces, QUANTUM statistics, TOPOLOGY

Abstract

The layered transition metal chalcogenides have been a fertile land in solid state physics for many decades. Various MX2-type transition metal dichalcogenides, such as WTe2, IrTe2, and MoS2, have triggered great attention recently, either for the discovery of novel phenomena or some extreme or exotic physical properties, or for their potential applications. PdTe2 is a superconductor in the class of transition metal dichalcogenides, and superconductivity is enhanced in its Cu-intercalated form, Cu0.05PdTe2. It is important to study the electronic structures of PdTe2 and its intercalated form in order to explore for new phenomena and physical properties and understand the related superconductivity enhancement mechanism. Here we report systematic high resolution angle-resolved photoemission (ARPES) studies on PdTe2 and Cu0.05PdTe2 single crystals, combined with the band structure calculations. We present in detail for the first time the complex multi-band Fermi surface topology and densely-arranged band structure of these compounds. By carefully examining the electronic structures of the two systems, we find that Cu-intercalation in PdTe2 results in electron-doping, which causes the band structure to shift downwards by nearly 16 meV in Cu0.05PdTe2. Our results lay a foundation for further exploration and investigation on PdTe2 and related superconductors. [ABSTRACT FROM AUTHOR]

Published

2015