Your search keyword '"Shimada, Kenya"' showing total 8 results

1. Electronic states in superconducting type-II Dirac semimetal: 1T-PdSeTe

Author

Kumar, Yogendra, Kumar, Shiv, Yenugonda, Venkateswara, Oishi, Ryohei, Nayak, Jayita, Chen, Chaoyu, Singh, Ravi Prakash, Onimaru, Takahiro, Shimura, Yasuyuki, Ideta, Shinichiro, and Shimada, Kenya

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

We have investigated the surface and bulk electronic structures of the superconducting type-II Dirac semimetal 1T-PdSeTe. The superconducting transition temperature $T_C = 3.2$ K was almost twice as high as $T_C = 1.6$ K in 1T-PdTe$_2$. Scanning transmission electron microscopy measurements showed homogeneously mixed Se and Te atoms in the chalcogen layers, consistent with the CdI$_2$-type crystal structure. Angle-resolved photoemission spectroscopy measurements and density functional theory calculations indicated the existence of the topological surface states, and the overall band structures were similar to those of 1T-PdTe$_2$. These results suggest that CdI$_2$-type lattice symmetry dictates the band dispersion, regardless of atomic disorder in the chalcogen layers. As the electronic band dispersion and the local structures were persistent upon substitution, the enhancement of $T_C$ is likely associated with the chemical pressure. Our results provide insight into the effects of the solid solution on the surface and bulk electronic states as well as the superconducting transition temperature., Comment: Quantum materials, Dirac semimetal, Weyl semimetal, Topological insulator, Topological superconductor, angle-resolved Photoemission spectroscopy, superconductivity

Published

2024

2. Evidence for Two-dimensional Weyl Fermions in Air-Stable Monolayer PtTe$_{1.75}$

Author

Cai, Zhihao, Cao, Haijun, Sheng, Haohao, Hu, Xuegao, Sun, Zhenyu, Zhao, Qiaoxiao, Gao, Jisong, Ideta, Shin-ichiro, Shimada, Kenya, Huang, Jiawei, Cheng, Peng, Chen, Lan, Yao, Yugui, Meng, Sheng, Wu, Kehui, Wang, Zhijun, and Feng, Baojie

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The Weyl semimetals represent a distinct category of topological materials wherein the low-energy excitations appear as the long-sought Weyl fermions. Exotic transport and optical properties are expected because of the chiral anomaly and linear energy-momentum dispersion. While three-dimensional Weyl semimetals have been successfully realized, the quest for their two-dimensional (2D) counterparts is ongoing. Here, we report the realization of 2D Weyl fermions in monolayer PtTe$_{1.75}$, which has strong spin-orbit coupling and lacks inversion symmetry, by combined angle-resolved photoemission spectroscopy, scanning tunneling microscopy, second harmonic generation, X-ray photoelectron spectroscopy measurements, and first-principles calculations. The giant Rashba splitting and band inversion lead to the emergence of three pairs of critical Weyl cones. Moreover, monolayer PtTe$_{1.75}$ exhibits excellent chemical stability in ambient conditions, which is critical for future device applications. The discovery of 2D Weyl fermions in monolayer PtTe$_{1.75}$ opens up new possibilities for designing and fabricating novel spintronic devices., Comment: Nano Letters, In Press

Published

2024

3. Crystal-symmetry-paired spin-valley locking in a layered room-temperature antiferromagnet

Author

Zhang, Fayuan, Cheng, Xingkai, Yin, Zhouyi, Liu, Changchao, Deng, Liwei, Qiao, Yuxi, Shi, Zheng, Zhang, Shuxuan, Lin, Junhao, Liu, Zhengtai, Ye, Mao, Huang, Yaobo, Meng, Xiangyu, Zhang, Cheng, Okuda, Taichi, Shimada, Kenya, Cui, Shengtao, Zhao, Yue, Cao, Guang-Han, Qiao, Shan, Liu, Junwei, and Chen, Chaoyu

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

Recent theoretical efforts predicted a type of unconventional antiferromagnet characterized by the crystal symmetry C (rotation or mirror), which connects antiferromagnetic sublattices in real space and simultaneously couples spin and momentum in reciprocal space. This results in a unique C-paired spin-valley locking (SVL) and corresponding novel properties such as piezomagnetism and noncollinear spin current even without spin-orbit coupling. However, the unconventional antiferromagnets reported thus far are not layered materials, limiting their potential in spintronic applications. Additionally, they do not meet the necessary symmetry requirements for nonrelativistic spin current. Here, we report the realization of C-paired SVL in a layered room-temperature antiferromagnetic compound, Rb1-{\delta}V2Te2O. Spin resolved photoemission measurements directly demonstrate the opposite spin splitting between C-paired valleys. Quasi-particle interference patterns reveal the suppression of inter-valley scattering due to the spin selection rules, as a direct consequence of C-paired SVL. All these experiments are well consistent with the results obtained from first-principles calculations. Our observations represent the first realization of layered antiferromagnets with C-paired SVL, enabling both the advantages of layered materials and possible control through crystal symmetry manipulation. These results hold significant promise and broad implications for advancements in magnetism, electronics, and information technology., Comment: 22 pages, 5 figures

Published

2024

4. Observation of Spin Splitting in Room-Temperature Metallic Antiferromagnet CrSb

Author

Zeng, Meng, Zhu, Ming-Yuan, Zhu, Yu-Peng, Liu, Xiang-Rui, Ma, Xiao-Ming, Hao, Yu-Jie, Liu, Pengfei, Qu, Gexing, Yang, Yichen, Jiang, Zhicheng, Yamagami, Kohei, Arita, Masashi, Zhang, Xiaoqian, Shao, Tian-Hao, Dai, Yue, Shimada, Kenya, Liu, Zhengtai, Ye, Mao, Huang, Yaobo, Liu, Qihang, and Liu, Chang

Subjects

Condensed Matter - Materials Science

Abstract

Recently, unconventional antiferromagnets that enable the splitting of electronic spins have been theoretically proposed and experimentally realized, where the magnetic sublattices containing moments pointing at different directions are connected by a novel set of symmetries. Such spin splitting (SS) is substantial, $k$-dependent, and independent of the spin-orbit coupling strength, making these magnets promising materials for antiferromagnetic spintronics. Here, combined with angle-resolved photoemission spectroscopy (ARPES) and density functional theory (DFT) calculations, we perform a systematic study on CrSb, a metallic spin-split antiferromagnet candidate with $T_N$ = 703 K. Our data reveals the electronic structure of CrSb along both out-of-plane and in-plane momentum directions, which renders anisotropic $k$-dependent SS and agrees well with the calculational results. The magnitude of such SS reaches up to at least 0.8 eV at non-high-symmetry momentum points, which is significantly higher than the largest known SOC-induced SS. This compound expands the choice of materials in the field of antiferromagnetic spintronics and is likely to stimulate subsequent investigations of high-efficiency spintronic devices that are functional at room temperature., Comment: 14 pages, 4 figures

Published

2024

5. Surface Electronic Structure of Cr Doped Bi 2 Se 3 Single Crystals.

Author

Yilmaz, Turgut, Tong, Xiao, Dai, Zhongwei, Sadowski, Jerzy T., Gu, Genda, Shimada, Kenya, Hwang, Sooyeon, Kisslinger, Kim, Vescovo, Elio, and Sinkovic, Boris

Subjects

PHOTOELECTRON spectroscopy, BAND gaps, THIN films, MAGNETIC impurities, SURFACE states

Abstract

Here, by using angle-resolved photoemission spectroscopy, we showed that Bi2−xCrxSe3 single crystals have a distinctly well-defined band structure with a large bulk band gap and undistorted topological surface states. These spectral features are unlike their thin film forms in which a large nonmagnetic gap with a distorted band structure was reported. We further provide laser-based high resolution photoemission data which reveal a Dirac point gap even in the pristine sample. The gap becomes more pronounced with Cr doping into the bulk of Bi2Se3. These observations show that the Dirac point can be modified by the magnetic impurities as well as the light source. [ABSTRACT FROM AUTHOR]

Published

2024

6. Evidence for Two-Dimensional Weyl Fermions in Air-Stable Monolayer PtTe1.75.

Author

Cai, Zhihao, Cao, Haijun, Sheng, Haohao, Hu, Xuegao, Sun, Zhenyu, Zhao, Qiaoxiao, Gao, Jisong, Ideta, Shin-ichiro, Shimada, Kenya, Huang, Jiawei, Cheng, Peng, Chen, Lan, Yao, Yugui, Meng, Sheng, Wu, Kehui, Wang, Zhijun, and Feng, Baojie

Published

2024

7. Visualization of spatial inhomogeneity in the superconducting gap using micro-ARPES.

Author

Miyai, Yudai, Ishida, Shigeyuki, Ozawa, Kenichi, Yoshida, Yoshiyuki, Eisaki, Hiroshi, Shimada, Kenya, and Iwasawa, Hideaki

Subjects

*HIGH temperature superconductors, *PHOTOELECTRON spectroscopy, *SCANNING tunneling microscopy, *SPATIAL resolution, *QUANTITATIVE research

Abstract

\nImpact statementElectronic inhomogeneity arises ubiquitously as a consequence of adjacent and/or competing multiple phases or orders in strongly correlated electron systems. Gap inhomogeneity in high-Tc cuprate superconductors has been widely observed using scanning tunneling microscopy/spectroscopy. However, it has yet to be evaluated by angle-resolved photoemission spectroscopy (ARPES) due to the difficulty in achieving both high energy and spatial resolutions. Here, we employ high-resolution spatially-resolved ARPES with a micrometric beam (micro-ARPES) to reveal the spatial dependence of the antinodal electronic states in optimally-doped Bi2Sr2CaCu2O8+δ. Detailed spectral lineshape analysis was extended to the spatial mapping dataset, enabling the identification of the spatial inhomogeneity of the superconducting gap and single-particle scattering rate at the micro-scale. Moreover, these physical parameters and their correlations were statistically evaluated. Our results suggest that high-resolution spatially-resolved ARPES holds promise for facilitating a data-driven approach to unraveling complexity and uncovering key parameters for the formulation of various physical properties of materials.This work pioneers high-resolution micro-ARPES for the first-time quantitative mapping and analysis of micro-scale superconducting gap inhomogeneity in high-Tc cuprate superconductors. [ABSTRACT FROM AUTHOR]

Published

2024

8. Evidence for Two-Dimensional Weyl Fermions in Air-Stable Monolayer PtTe 1.75 .

Author

Cai Z, Cao H, Sheng H, Hu X, Sun Z, Zhao Q, Gao J, Ideta SI, Shimada K, Huang J, Cheng P, Chen L, Yao Y, Meng S, Wu K, Wang Z, and Feng B

Abstract

The Weyl semimetals represent a distinct category of topological materials wherein the low-energy excitations appear as the long-sought Weyl Fermions. Exotic transport and optical properties are expected because of the chiral anomaly and linear energy-momentum dispersion. While three-dimensional Weyl semimetals have been successfully realized, the quest for their two-dimensional (2D) counterparts is ongoing. Here, we report the realization of 2D Weyl Fermions in monolayer PtTe 1.75 , which has strong spin-orbit coupling and lacks inversion symmetry, by combined angle-resolved photoemission spectroscopy, scanning tunneling microscopy, second harmonic generation, X-ray photoelectron spectroscopy measurements, and first-principles calculations. The giant Rashba splitting and band inversion lead to the emergence of three pairs of critical Weyl cones. Moreover, monolayer PtTe 1.75 exhibits excellent chemical stability in ambient conditions, which is critical for future device applications. The discovery of 2D Weyl Fermions in monolayer PtTe 1.75 opens up new possibilities for designing and fabricating novel spintronic devices.

Published

2024