Your search keyword '"Xiang, Jun-Sen"' showing total 8 results

1. NdAlSi: a magnetic Weyl semimetal candidate with rich magnetic phases and atypical transport properties

Author

Wang, Jin-Feng, Dong, Qing-Xin, Guo, Zhao-Peng, Lv, Meng, Huang, Yi-Fei, Xiang, Jun-Sen, Ren, Zhi-An, Wang, Zhi-Jun, Sun, Pei-Jie, Li, Gang, and Chen, Gen-Fu

Subjects

Condensed Matter - Materials Science

Abstract

Magnetic Weyl semimetals (MWSM) have attracted significant attention due to their intriguing physical properties and potential applications in spin-electronic devices. Here we report the characterization of NdAlSi including transport, magnetization, and heat capacity on single crystals, as well as band structure calculation. It is a newly proposed MWSM candidate which breaks both time-reversal and spacial inversion symmetries. A temperature-magnetic field phase diagram is experimentally established. Remarkably, on the angular magnetoresistance (AMR), a two-fold symmetric sharp peak instead of a smooth variation is observed in the field-induced ferrimagnetic phase. We argue that the tunability of both the topological and magnetic properties in NdAlSi is crucial for realizing such a behavior. Our results indicate that 4f-electron-based MWSM can provide a unique platform to explore new and intriguing quantum phenomena arising from the interaction between magnetism and topology., Comment: 24 pages, 12 figures

Published

2022

2. Enhanced longitudinal and transverse thermopowers at low temperature in quasi-one-dimensional antiferromagnet KMn6Bi5

Author

Dong, Qing-xin, primary, Huang, Yi-fei, additional, Zhang, Li-bo, additional, Bai, Jian-li, additional, Cheng, Jing-wen, additional, Liu, Qiao-yu, additional, Liu, Pin-yu, additional, Li, Cun-dong, additional, Xiang, Jun-sen, additional, Wang, Jin-feng, additional, Ruan, Bin-Bin, additional, Ren, Zhi-an, additional, Sun, Pei-jie, additional, and Chen, Gen-fu, additional

Published

2023

3. NdAlSi: A magnetic Weyl semimetal candidate with rich magnetic phases and atypical transport properties

Author

Wang, Jin-Feng, primary, Dong, Qing-Xin, additional, Guo, Zhao-Peng, additional, Lv, Meng, additional, Huang, Yi-Fei, additional, Xiang, Jun-Sen, additional, Ren, Zhi-An, additional, Wang, Zhi-Jun, additional, Sun, Pei-Jie, additional, Li, Gang, additional, and Chen, Gen-Fu, additional

Published

2022

4. Criticality-Enhanced Magnetocaloric Effect in Quantum Spin Chain Material Copper Nitrate

Author

Xiang, Jun-Sen, Chen, Cong, Li, Wei, Sheng, Xian-Lei, Su, Na, Cheng, Zhao-Hua, Chen, Qiang, and Chen, Zi-Yu

Published

2017

5. Electric and thermal transport properties of topological insulator candidate LiMgBi*

Author

OuYang, Hao, primary, Dong, Qing-Xin, additional, Huang, Yi-Fei, additional, Xiang, Jun-Sen, additional, Zhang, Li-Bo, additional, Li, Chen-Sheng, additional, Sun, Pei-Jie, additional, Ren, Zhi-An, additional, and Chen, Gen-Fu, additional

Published

2021

6. Enhanced longitudinal and transverse thermopowers at low temperature in quasi-one-dimensional antiferromagnet KMn6Bi5.

Author

Dong, Qing-xin, Huang, Yi-fei, Zhang, Li-bo, Bai, Jian-li, Cheng, Jing-wen, Liu, Qiao-yu, Liu, Pin-yu, Li, Cun-dong, Xiang, Jun-sen, Wang, Jin-feng, Ruan, Bin-Bin, Ren, Zhi-an, Sun, Pei-jie, and Chen, Gen-fu

Subjects

LOW temperatures, THERMOELECTRIC power, SEEBECK coefficient, ANTIFERROMAGNETIC materials, ELECTRIC conductivity, THERMOELECTRICITY

Abstract

Finding promising materials that show large thermoelectricity at low temperatures is crucial for low-temperature refrigeration applications. Here, we report a significantly large thermoelectric power factor (PF) up to 50 μW cm−1 K−2 at an extremely low temperature of ∼8 K in a quasi-one-dimensional (Q1D) antiferromagnet KMn6Bi5, in which highly electrical conductivity and dramatic enhancement of Seebeck coefficient may favor its occurrence. In addition, a giant Nernst signal has also been detected with a maximum value of 24 μV K−1 T−1 at ∼5 K. All these intriguing characteristics observed in KMn6Bi5 can be attributed to the manifestation of the unusually strong coupling among spin, charge, lattice, and one dimensionality in KMn6Bi5. Our findings provide fundamental insight into the thermal transport in Q1D antiferromagnets and should stimulate further experimental exploration of thermal transport in such Q1D family for possible thermoelectric applications at extremely low temperatures. [ABSTRACT FROM AUTHOR]

Published

2023

7. The manipulation of magnetic coercive field and orientation of magnetic anisotropy via electric fields

Author

Xiang, Jun-Sen, primary, Ye, Jun, additional, Yang, Yun-Long, additional, Xie, Yong, additional, Li, Wei, additional, and Chen, Zi-Yu, additional

Published

2016

8. Enhanced longitudinal and transverse thermopowers at low temperature in quasi-one-dimensional antiferromagnet KMn6Bi5.

Author

Dong, Qing-xin, Huang, Yi-fei, Zhang, Li-bo, Bai, Jian-li, Cheng, Jing-wen, Liu, Qiao-yu, Liu, Pin-yu, Li, Cun-dong, Xiang, Jun-sen, Wang, Jin-feng, Ruan, Bin-Bin, Ren, Zhi-an, Sun, Pei-jie, and Chen, Gen-fu

Subjects

*LOW temperatures, *THERMOELECTRIC power, *SEEBECK coefficient, *ANTIFERROMAGNETIC materials, *ELECTRIC conductivity, *THERMOELECTRICITY

Abstract

Finding promising materials that show large thermoelectricity at low temperatures is crucial for low-temperature refrigeration applications. Here, we report a significantly large thermoelectric power factor (PF) up to 50 μW cm−1 K−2 at an extremely low temperature of ∼8 K in a quasi-one-dimensional (Q1D) antiferromagnet KMn6Bi5, in which highly electrical conductivity and dramatic enhancement of Seebeck coefficient may favor its occurrence. In addition, a giant Nernst signal has also been detected with a maximum value of 24 μV K−1 T−1 at ∼5 K. All these intriguing characteristics observed in KMn6Bi5 can be attributed to the manifestation of the unusually strong coupling among spin, charge, lattice, and one dimensionality in KMn6Bi5. Our findings provide fundamental insight into the thermal transport in Q1D antiferromagnets and should stimulate further experimental exploration of thermal transport in such Q1D family for possible thermoelectric applications at extremely low temperatures. [ABSTRACT FROM AUTHOR]

Published

2023