Your search keyword '"Zhao, W. X."' showing total 6 results

1. Topological Phase Transition in Quasi-One-Dimensional Bismuth Iodide Bi4I4

Author

Zhao, W. X., Yang, M., Du, X., Li, Y. D., Zhai, K. Y., Hu, Y. Q., Han, J. F., Huang, Y., Liu, Z. K., Yao, Y. G., Zhuang, J. C., Du, Y., Zhou, J. J., Chen, Y. L., and Yang, L. X.

Subjects

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

Abstract

The exploration of topological quantum materials and topological phase transitions is at the forefront of modern condensed matter physics. Quasi-one-dimensional (quasi-1D) bismuth iodide Bi4I4 exhibits versatile topological phases of matter including weak topological insulator (WTI) and higher-order topological insulator (HOTI) phases with high tunability in response to external parameters. In this work, performing laser-based angle-resolved photoemission spectroscopy with submicron spatial resolution (micro-ARPES), we comprehensively investigate the fine electronic structure and topological phase transition of Bi4I4. Our examination of the low-temperature {\alpha}-phase reveals the presence of an energy gap on the (100) surface, providing spectroscopic evidence for the HOTI phase. Conversely, the high-temperature {\beta}-Bi4I4 harbors a gapless Dirac fermion on the (100) surface alongside gapped states on the (001) surface, thereby establishing a WTI phase. By tracking the temperature evolution of the (100) surface states, we unveil a thermal hysteresis of the surface gap in line with the {\alpha}-{\beta} structural phase transition. Our findings elucidate the topological properties of Bi4I4 and directly evidence a temperature-induced topological phase transition from WTI to HOTI, which paves the way to potential applications based on the room-temperature topological phase transition in the quasi-1D topological quantum material.

Published

2024

2. Correlated Electronic Structure and Density-Wave Gap in Trilayer Nickelate La4Ni3O10

Author

Du, X., Li, Y. D., Cao, Y. T., Pei, C. Y., Zhang, M. X., Zhao, W. X., Zhai, K. Y., Xu, R. Z., Liu, Z. K., Li, Z. W., Zhao, J. K., Li, G., Chen, Y. L., Qi, Y. P., Guo, H. J., and Yang, L. X.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons

Abstract

The discovery of pressurized superconductivity at 80 K in La3Ni2O7 officially brings nickelates into the family of high-temperature superconductors, which gives rise to not only new insights but also mysteries in the strongly correlated superconductivity. More recently, the sibling compound La4Ni3O10 was also shown to be superconducting below about 25 K under pressure, further boosting the popularity of nickelates in the Ruddlesden-Popper phase. In this study, combining high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we systematically investigate the electronic structures of La4Ni3O10 at ambient pressure. We reveal a high resemblance of La4Ni3O10 with La3Ni2O7 in the orbital-dependent fermiology and electronic structure, suggesting a similar electronic correlation between the two compounds. The temperature-dependent measurements imply an orbital-dependent energy gap related to the density-wave transition in La4Ni3O10. By comparing the theoretical pressure-dependent electronic structure, clues about the superconducting high-pressure phase can be deduced from the ambient measurements, providing crucial information for deciphering the unconventional superconductivity in nickelates.

Published

2024

3. Topological electronic structure and spin texture of quasi-one-dimensional higher-order topological insulator Bi4Br4

Author

Zhao, W. X., Yang, M., Xu, R. Z., Du, X., Li, Y. D., Zhai, K. Y., Peng, C., Pei, D., Gao, H., Li, Y. W., Xu, L. X., Han, J. F., Huang, Y., Liu, Z. K., Yao, Y. G., Zhuang, J. C., Du, Y., Zhou, J. J., Chen, Y. L., and Yang, L. X.

Subjects

Condensed Matter - Materials Science

Abstract

The notion of topological insulators (TIs), characterized by an insulating bulk and conducting topological surface states, can be extended to higher-order topological insulators (HOTIs) hosting gapless modes localized at the boundaries of two or more dimensions lower than the insulating bulk1-5. In this work, by performing high-resolution angle-resolved photoemission spectroscopy (ARPES) measurements with submicron spatial and spin resolutions, we systematically investigate the electronic structure and spin texture of quasi-one-dimensional (1D) HOTI candidate Bi4Br4. In contrast to the bulk-state-dominant spectra on the (001) surface, we observe gapped surface states on the (100) surface, whose dispersion and spin-polarization agree well with our ab initio calculations. Moreover, we reveal in-gap states connecting the surface valence and conduction bands, which is an explicit signature of the existence of hinge states inside the (100) surface gap. Our findings provide compelling evidence for the HOTI phase of Bi4Br4. The identification of the higher-order topological phase will lay the promising prospect of applications based on 1D spin-momentum locked current in electronic and spintronic devices.

Published

2023

4. Orbital-selective charge-density wave in TaTe$_4$

Author

Xu, R. Z., Du, X., Zhou, J. S., Gu, X., Zhang, Q. Q., Li, Y. D., Zhao, W. X., Zheng, F. W., Arita, M., Shimada, K., Kim, T. K., Cacho, C., Guo, Y. F., Liu, Z. K., Chen, Y. L., and Yang, L. X.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

TaTe$_4$, a metallic charge-density wave (CDW) material discovered decades ago, has attracted renewed attention due to its rich interesting properties such as pressure-induced superconductivity and candidate non-trivial topological phase. Here, using high-resolution angle-resolved photoemission spectroscopy and ab-initio calculation, we systematically investigate the electronic structure of TaTe$_4$. At 26 K, we observe a CDW gap as large as 290 meV, which persists up to 500 K. The CDW-modulated band structure shows a complex reconstruction that closely correlates with the lattice distortion. Inside the CDW gap, there exist highly dispersive energy bands contributing to the remnant Fermi surface and metallic behavior in the CDW state. Interestingly, our ab-initio calculation reveals that the large CDW gap mainly opens in the electronic states with out-of-plane orbital components, while the in-gap metallic states originate from in-plane orbitals, suggesting an orbital texture that couples with the CDW order. Our results shed light on the interplay between electron, lattice, and orbital in quasi-one-dimensional CDW materials., Comment: to appear in npj Quantum Materials

Published

2023

5. Development of a Laser-based angle-resolved-photoemission spectrometer with sub-micrometer spatial resolution and high-efficiency spin detection

Author

Xu, R. Z., Gu, X., Zhao, W. X., Zhou, J. S., Zhang, Q. Q., Du, X., Li, Y. D., Mao, Y. H., Zhao, D., Huang, K., Zhang, C. F., Wang, F., Liu, Z. K., Chen, Y. L., and Yang, L. X.

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

Angle-resolved photoemission spectroscopy with sub-micrometer spatial resolution ({\mu}-ARPES), has become a powerful tool for studying quantum materials. To achieve sub-micrometer or even nanometer-scale spatial resolution, it is important to focus the incident light beam (usually from the synchrotron radiation) using X-ray optics such as the zone plate or ellipsoidal capillary mirrors. Recently, we developed a laser-based {\mu}-ARPES with spin-resolution (LMS-ARPES). The 177 nm laser beam is achieved by frequency doubling a 355 nm beam using a KBBF crystal and subsequently focused using an optical lens with a focal length of about 16 mm. By characterizing the focused spot size using different methods and performing spatial-scanning photoemission measurement, we confirm the sub-micron spatial resolution of the system. Compared with the {\mu}-ARPES facilities based on synchrotron radiation, our LMS-ARPES system is not only more economical and convenient but also with higher photon flux (> 5E13 photons/s), thus enabling the high-resolution and high-statistics measurements. Moreover, the system is equipped with a two-dimensional spin detector based on exchange scattering at a surface-passivated iron film grown on a W(100) substrate. We investigate the spin structure of the prototype topological insulator Bi2Se3 and reveal a high spin-polarization rate, confirming its spin-momentum locking property. This lab-based LMS-ARPES will be a powerful research tool for studying the local fine electronic structures of different condensed matter systems, including topological quantum materials, mesoscopic materials and structures, and phase-separated materials., Comment: To appear in RSI

Published

2023

6. Crossed Luttinger Liquid Hidden in a Quasi-two-dimensional Material {\eta}-Mo4O11

Author

Du, X., Kang, L., Lv, Y. Y., Zhou, J. S., Gu, X., Xu, R. Z., Zhang, Q. Q., Yin, Z. X., Zhao, W. X., Li, Y. D., He, S. M., Pei, D., Chen, Y. B., Wang, M. X., Liu, Z. K., Chen, Y. L., and Yang, L. X.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Although the concept of Luttinger liquid (LL) that describes a one-dimensional (1D) interacting fermion system collapses in higher dimensions, it has been proposed to be closely related to many mysteries including the normal state of cuprate superconductor, unconventional metal, and quantum criticality. Therefore, the generalization of LL model to higher dimensions has attracted substantial research attention. Here we systematically investigate the electronic structure of a quasi-2D compound {\eta}-Mo4O11 using high-resolution angle-resolved photoemission spectroscopy and ab-initio calculation. Remarkably, we reveal a prototypical LL behavior originating from the crossing quasi-1D chain arrays hidden in the quasi-2D crystal structure. Our results suggest that {\eta}-Mo4O11 materializes the long sought-after crossed LL phase, where the orthogonal orbital components significantly reduce the coupling between intersecting quasi-1D chains and therefore maintain the essential properties of LL. Our finding not only presents a realization of 2D LL, but also provides a new angle to understand non-Fermi liquid behaviors in other 2D and 3D quantum materials.

Published

2022