Your search keyword '"Deng T"' showing total 3 results

1. Measurement of Electronic Structure and Surface Reconstruction in the Superionic Cu2-xTe

Author

Liu, S., Xia, W., Huang, K., Pei, D., Deng, T., Liang, A. J., Jiang, J., Yang, H. F., Zhang, J., Zheng, H. J., Chen, Y. J., Yang, L. X., Guo, Y. F., Wang, M. X., Liu, Z. K., and Chen, Y. L.

Subjects

Condensed Matter - Materials Science

Abstract

Recently, layered copper chalcogenides Cu2X family (X=S, Se, Te) has attracted tremendous research interests due to their high thermoelectric (TE) performance, which is partly due to the superionic behavior of mobile Cu ions, making these compounds phonon liquids. Here, we systematically investigate the electronic structure and its temperature evolution of the less studied single crystal Cu2-xTe by the combination of angle resolved photoemission spectroscopy (ARPES) and scanning tunneling microscope/spectroscopy (STM/STS) experiments. While the band structure of the Cu2-xTe shows agreement with the calculations, we clearly observe a 2 * 2 surface reconstruction from both our low temperature ARPES and STM/STS experiments which survives up to room temperature. Interestingly, our low temperature STM experiments further reveal multiple types of reconstruction patterns, which suggests the origin of the surface reconstruction being the distributed deficiency of liquid-like Cu ions. Our findings reveal the electronic structure and impurity level of Cu2Te, which provides knowledge about its thermoelectric properties from the electronic degree of freedom.

Published

2021

2. Evidence of topological edge states in a superconducting nonsymmorphic nodal-line semimetal

Author

Xu, L. X., Xia, Y. Y. Y., Liu, S., Li, Y. W., Wei, L. Y., Wang, H. Y., Wang, C. W., Yang, H. F., Liang, A. J., Huang, K., Deng, T., Xia, W., Zhang, X., Zheng, H. J., Chen, Y. J., Yang, L. X., Wang, M. X., Guo, Y. F., Li, G., Liu, Z. K., and Chen, Y. L.

Subjects

Condensed Matter - Materials Science

Abstract

Topological materials host fascinating low dimensional gapless states at the boundary. As a prominent example, helical topological edge states (TESs) of two-dimensional topological insulators (2DTIs) and their stacked three-dimensional (3D) equivalent, weak topological insulators (WTIs), have sparked research enthusiasm due to their potential application in the next generation of electronics/spintronics with low dissipation. Here, we propose layered superconducting material CaSn as a WTI with nontrivial Z2 as well as nodal line semimetal protected by crystalline non-symmorphic symmetry. Our systematic angle-resolved photoemission spectroscopy (ARPES) investigation on the electronic structure exhibits excellent agreement with the calculation. Furthermore, scanning tunnelling microscopy/spectroscopy (STM/STS) at the surface step edge shows signatures of the expected TES. These integrated evidences from ARPES, STM/STS measurement and corresponding ab initio calculation strongly support the existence of TES in the non-symmorphic nodal line semimetal CaSn, which may become a versatile material platform to realize multiple exotic electronic states as well as topological superconductivity.

Published

2021

3. Determination of the positions and orientations of concentrated rod-like colloids from 3D microscopy data

Author

Besseling, T. H., Hermes, M., Kuijk, A., de Nijs, B., Deng, T. -S., Dijkstra, M., Imhof, A., and van Blaaderen, A.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Confocal microscopy in combination with real-space particle tracking has proven to be a powerful tool in scientific fields such as soft matter physics, materials science and cell biology. However, 3D tracking of anisotropic particles in concentrated phases remains not as optimized compared to algorithms for spherical particles. To address this problem, we developed a new particle-fitting algorithm that can extract the positions and orientations of fluorescent rod-like particles from three dimensional confocal microscopy data stacks, even when the fluorescent signals of the particles overlap considerably. We demonstrate that our algorithm correctly identifies all five coordinates of uniaxial particles in both a concentrated disordered phase and a liquid-crystalline smectic-B phase. Apart from confocal microscopy images, we also demonstrate that the algorithm can be used to identify nanorods in 3D electron tomography reconstructions. Lastly, we determined the accuracy of the algorithm using both simulated and experimental confocal microscopy data-stacks of diffusing silica rods in a dilute suspension. This novel particle-fitting algorithm allows for the study of structure and dynamics in both dilute and dense liquid-crystalline phases (such as nematic, smectic and crystalline phases) as well as the study of the glass transition of rod-like particles in three dimensions on the single particle level., Comment: 6 figures, 1 table

Published

2014