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2,867 results on '"Zhang, Jian-Min"'

1. Hybrid-Order Topological Phase And Transition in 1H Transition Metal Compounds

Author

Yang, Ning-Jing, Huang, Zhigao, and Zhang, Jian-Min

Subjects
Condensed Matter - Materials Science, Quantum Physics
Abstract

Inspired by recent experimental observations of hybrid topological states [Nature 628, 527 (2024)], we predict hybrid-order topological insulators (HOTIs) in 1H transition metal compounds (TMCs), where both second-order and first-order topological states coexist near the Fermi level. Initially, 1H-TMCs exhibit a second-order topological phase due to the d-orbital band gap. Upon coupling of p- and d- orbitals couple, first-order topological characteristics emerge. This hybrid-order topological phase transition is tunable via crystal field effects. Combined with first-principles calculations, we illustrate the phase transition with WTe2 and NbSe2. In addition, the first-order topological band gap of the HOTI exhibits a strong spin Hall effect. Our finding reveal novel hybrid-order topological phase in 2D electron materials and highlight spintronic applications., Comment: 6 gages, 4 figures

Published
2024

2. Thermal and mechanical properties and the structural phase transition under pressure in $A$In$_2$As$_2$ ($A$ = Ca, Sr, Ba)

Author

Guo, Wen-Ti, Huang, Zhigao, and Zhang, Jian-Min

Subjects
Condensed Matter - Materials Science
Abstract

Experimental results that BaIn2As2 and Ca(Sr)In2As2, which are the same class of alkali metal compounds, belong to different structural phases have puzzled the current materials physics community. Here, we investigate the pressure-induced structural phase transition of AIn2As2 and its accompanying improvement in mechanical and thermal properties. Firstly, the structural stability of the materials and their structural phase transitions under pressure are characterized by enthalpy and double checking by phonon dispersion spectrum. We also confirm the structural phase transitions of the hexagonal and monoclinic phases from a group-theoretic point of view, associating their symmetry operations using transformation matrices. In terms of mechanical properties, we propose an effective scheme for pressure modulation of the anisotropy of AIn2As2 materials and to induce the transformation of AIn2As2 from isotropic to anisotropic (hexagonal) and from brittle to ductile (hexagonal and monoclinic). Meanwhile, we find the negative Poisson's ratio phenomenon under compression and tension, which is favorable for a wide range of applications of this series of materials in aerospace, medicine, sensors, etc. In terms of thermal properties, applying pressure will enhance the structural phase transition temperature of AIn2As2 materials to near room temperature. We further give direct evidence of phonon softening based on group velocity calculations and reveal that phonon softening prevents the heat capacity from reaching the Dulong-Petit limit. Our study provides a theoretical basis for selecting stable structural phases and pioneering thermodynamic property studies of the thermoelectric topological candidate material AIn2As2., Comment: 22 pages, 13 figures

Published
2024
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5. High-Order Topological Phase Diagram Revealed by Anomalous Nernst Effect in Janus ScClI Monolayer

Author

Yang, Ning-Jing and Zhang, Jian-Min

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Higher-order topological properties of two-dimensional(2D) magnetic materials have recently been proposed. In 2D ferromagnetic Janus materials, we find that ScClI is a second-order topological insulator (SOTI). By means of a multi-orbital tight-binding model, we analyze the orbital contributions of higher-order topologies. Further, we give the complete high-order topological phase diagram of ScClI, based on the external field modulation of the magneto-valley coupling and energy levels. 2D ScClI has a pronounced valley polarization, which causes different insulating phases to exhibit completely different anomalous Nernst conductance. As a result, we use the matched anomalous Nernst effect to reveal the topological phase transition process of ScClI. We utilize the characteristics of valley electronics to link higher-order topological materials with the anomalous Nernst effect, which has potential implications for high-order topological insulators and valley electronics., Comment: 6 pages, 3 pages

Published
2023
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6. Topological Phases, Local Magnetic Moments, and Spin Polarization Triggered by C558-Line Defects in Graphene

Author

Yang, Ning-Jing, Guo, Wen-Ti, Yang, Hai, Huang, Zhigao, and Zhang, Jian-Min

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study the electronic properties of a novel topological defect structure for graphene interspersed with C558-line defects along the Armchair boundary. This system has the topological property of being topologically three-periodic and the type-II Dirac-fermionic character of the embedded topological phase. At the same time, we show computationally that the topological properties of the system are overly dependent on the coupling of this line defect. Using strain engineering to regulate the magnitude of hopping at the defect, the position of the energy level can be easily changed to achieve a topological phase transition. We also discuss the local magnetic moment and the ferromagnetic ground state in the context of line defects, which is the conclusion after considering additional Coulomb interactions. This leads to spin polarization of the whole system. Finally, by modulating the local magnetic moment at the position of the line defect, we achieve a tunable spin quantum conductance in a one-dimensional nanoribbon. Near the Fermi energy level, it also has the property of complete spin polarization. Consequently, spin filtering can be achieved by varying the incident energy of the electrons., Comment: 8 pages, 6 figures

Published
2023

7. Novel magnetic topological insulator FeBi$_2$Te$_4$ with controllable topological quantum phase

Author

Guo, Wen-Ti, Yang, Ningjing, Huang, Zhigao, and Zhang, Jian-Min

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Here, we report a new intrinsic magnetic topological insulator FeBi$_2$Te$_4$ based on first-principles calculations and it can achieve a rich topological phase under pressure modulation. Without pressure, we predict that both FeBi$_2$Te$_4$ ferromagnetic and antiferromagnetic orders are non-trivial topological insulators. Furthermore, FeBi$_2$Te$_4$ of FM-z order will undergo a series of phase transitions from topological insulator to semimetals and then to trivial insulator under pressure. Finally, we further clarify and verify topological phase transitions with low-energy effective model calculations. This topological phase transition process is attributed to the synergy of the magnetic moment and the spin-orbit coupling. The unique topological properties of FeBi$_2$Te$_4$ will be of great interest in driving the development of quantum effects.

Published
2023
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10. LEAP-ASIA-2019 Simulation Exercise: Calibration of Constitutive Models and Simulations of the Element Tests

Author

Ueda, Kyohei, Tanaka, Yoshikazu, Sahare, Anurag, Elgamal, Ahmed, Qiu, Zhijian, Wang, Rui, Zhu, Tong, Zhou, Chuang, Zhang, Jian-Min, Parra, Andres Reyes, Barrero, Andres, Taiebat, Mahdi, Yuyama, Waka, Iai, Susumu, Hyodo, Junichi, Ichii, Koji, Elbadawy, Mohamed A., Zhou, Yan-Guo, Fasano, Gianluca, Chiaradonna, Anna, Bilotta, Emilio, Arduino, Pedro, Zeghal, Mourad, Manzari, Majid, Tobita, Tetsuo, Tobita, Tetsuo, editor, Ichii, Koji, editor, and Ueda, Kyohei, editor

Published
2024
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11. LEAP-ASIA-2019 Simulation Exercise: Comparison of the Type-B and Type-C Numerical Simulations with Centrifuge Test Results

Author

Ueda, Kyohei, Tanaka, Yoshikazu, Sahare, Anurag, Elgamal, Ahmed, Qiu, Zhijian, Wang, Rui, Zhu, Tong, Zhou, Chuang, Zhang, Jian-Min, Parra, Andres Reyes, Barrero, Andres, Taiebat, Mahdi, Yuyama, Waka, Iai, Susumu, Hyodo, Junichi, Ichii, Koji, Elbadawy, Mohamed A., Zhou, Yan-Guo, Fasano, Gianluca, Chiaradonna, Anna, Bilotta, Emilio, Arduino, Pedro, Zeghal, Mourad, Manzari, Majid, Tobita, Tetsuo, Tobita, Tetsuo, editor, Ichii, Koji, editor, and Ueda, Kyohei, editor

Published
2024
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12. Topological flatbands in kagome lattice CaCu5: A first-principles study.

Author

Ye, Jiefeng, Xu, Chenyu, and Zhang, Jian-Min

Subjects
TOPOLOGICAL property, PHENOMENOLOGICAL theory (Physics), EIGENVALUES, SYMMETRY
Abstract

Topological flatband materials have garnered significant attention due to their strongly correlated electronic states. Here, we propose the typical flatband and topological features in the classical copper-based kagome lattice CaCu 5. Our work confirms the stability of the CaCu 5 system. Notably, we identify flatbands in the band structure of the CaCu 5 system, accompanied by a typical quadratic band with line touching, and the flatness of flatbands is broken when spin–orbit coupling is introduced. Furthermore, parity and symmetry eigenvalue calculations of the wavefunctions reveal the nontrivial topological properties of the system. Our results suggest that the CaCu 5 system, with its topological flatbands, serves as an ideal platform for studying strong correlation effects and novel physical phenomena. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Dose adjustment of paroxetine based on CYP2D6 activity score inferred metabolizer status in Chinese Han patients with depressive or anxiety disorders: a prospective study and cross-ethnic meta-analysis

Author

Liao, Yundan, Sun, Yutao, Guo, Jing, Kang, Zhewei, Sun, Yaoyao, Zhang, Yuyanan, Bai, Hanping, Hu, Maolin, Li, Bing, Han, Jingshan, Xiang, Jiaojiao, Jiang, Ruhong, Zhang, Jian, He, Yuxiang, Yang, Huailiang, Liu, Guifang, Peng, Lili, Yu, Hui, Cheng, Xialong, Fang, Wenmei, Zheng, Rongyan, Lin, Ruiqian, Zhai, Xiao-yan, Tang, Rui, Deng, Fangyi, Zhu, Chunyan, Zhang, Ting, Yang, Yan, Geng, Ji-ting, Wu, Di, Chen, Yi-huan, Sun, Yifan, Zhou, Yong-can, Wang, Wei-xin, Zhang, Jian-min, Wang, Jun, Wang, Hua-ning, Chen, Zhi-yu, Wang, Kai, Pan, Jiyang, Ni, Ai-hua, Weng, Saizheng, Wang, Anzhen, Cao, Changbin, Sun, Lidong, Zhang, Yong, Kuang, Li, Zhang, Yunshu, Liu, Zhongchun, Yue, Weihua, He, Jiong, Huang, Chengchen, and Sun, Xin

Published
2024
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29. Topological quantum phase transition in the magnetic semimetal HoSb

Author

Zhang, Jian-Min, Tang, Fang, Ruan, Yurong, Chen, Y., Zhang, Runwu, Guo, Wenti, Chen, Shuiyuan, Li, Jianping, Zhao, Weiyao, Zhou, W., Zhang, Lei, Han, Zhida, Qian, Bin, Jiang, Xuefan, Huang, Zhigao, Qian, Dong, and Fang, Yong

Subjects
Condensed Matter - Materials Science
Abstract

Magnetic topological semimetals, a novel state of quantum matter with nontrivial band topology, have emerged as a new frontier in physics and materials science. An external stimulus like temperature or magnetic field could be expected to alter their spin states and thus the Fermi surface anisotropies and topological features. Here, we perform the angular magnetoresistance measurements and electronic band structure calculations to reveal the evolution of HoSb's Fermi surface anisotropies and topological nature in different magnetic states. The angular magnetoresistance results manifest that its Fermi surface anisotropy is robust in the paramagnetic state but is significantly modulated in the antiferromagnetic and ferromagnetic states. More interestingly, a transition from the trivial (nontrivial) to nontrivial (trivial) topological electronic phase is observed when HoSb undergoes a magnetic transition from the paramagnetic (antiferromagnetic) to antiferromagnetic (ferromagnetic) state induced by temperature (applied magnetic field). Our studying suggests that HoSb provides an archetype platform to study the correlations between magnetism and topological states of matter., Comment: 27 pages, 9 figures.Accepted paper

Published
2021

30. Weyl Nodal Line-Surface Half-metal in CaFeO$_3$

Author

Zhang, Run-Wu, Ma, Da-Shuai, Zhang, Jian-Min, and Yao, Yugui

Subjects
Condensed Matter - Materials Science
Abstract

Manipulating the spin degrees of freedom of electrons affords an excellent platform for exploring novel quantum states in condensed-matter physics and material science. Based on first-principles calculations and analysis of crystal symmetries, we propose a fully spin-polarized composite semimetal state, which is combined with the one-dimensional nodal lines and two-dimensional nodal surfaces, in the half-metal material CaFeO$_3$. In the nodal line-surface states, the Baguenaudier-like nodal lines feature six rings linked together, which are protected by the three independent symmetry operations:$\mathcal{PT}$, $\mathcal{M}_{y}$, and $\mathcal{\widetilde{M}}_{z}$. Near the Fermi level, the spin-polarized nodal surface states are guaranteed by the joint operation $\mathcal{T}\mathcal{S}_{2i}$ in the $k_{i(i=x,y,z)}=\pi$ plane. Furthermore, high-quality CaFeO$_3$ harbors ultra-clean energy dispersion, which is rather robust against strong triaxial compressional strain and correlation effect. The realization of the Weyl nodal line-surface half-metal presents great potential for spintronics applications with high speed and low power consumption., Comment: 5 figures + 1 table

Published
2021
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39. Centrifuge and Numerical Simulation of Offshore Wind Turbine Suction Bucket Foundation Seismic Response in Inclined Liquefiable Ground

Author

Qu, Xue-Qian, Wang, Rui, Zhang, Jian-Min, He, Ben, Ansal, Atilla, Series Editor, Bommer, Julian, Editorial Board Member, Bray, Jonathan D., Editorial Board Member, Pitilakis, Kyriazis, Editorial Board Member, Yasuda, Susumu, Editorial Board Member, Wang, Lanmin, editor, Zhang, Jian-Min, editor, and Wang, Rui, editor

Published
2022
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49. Adsorption and ultrafast diffusion of lithium in bilayer graphene ab initio and kinetic Monte Carlo simulation study

Author

Zhong, Kehua, Hu, Ruina, Xu, Guigui, Yang, Yanmin, Zhang, Jian-Min, and Huang, Zhigao

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this work, we adopt first-principle calculations based on density functional theory and Kinetic Monte Carlo simulations to investigate the adsorption and diffusion of lithium in bilayer graphene (BLG) as anodes in lithium-ion batteries. Based on energy barriers directly obtained from first-principle calculations for single-Li and two-Li intercalated BLG, a new equation was deduced for predicting energy barriers considering Li's interactions for multi-Li intercalated BLG. Our calculated results indicate that Li energetically prefers to intercalate within rather than adsorb outside the bilayer graphene. Additionally, lithium exists in cationic state in the bilayer graphene. More excitingly, ultrafast Li diffusion coefficient, within AB-stacked BLG near room temperature was obtained, which reproduces the ultrafast Li diffusion coefficient measured in recent experiment. However, ultrafast Li diffusion was not found within AA-stacked BLG near room temperature. The analyses of potential distribution indicate that the stacking structure of BLG greatly affects its height of potential well within BLG, which directly leads to the large difference in Li diffusion. Furthermore, it is found that both the interaction among Li ions and the stacking, structure cause Li diffusion within AB-stacked BLG to exhibit directional preference. Finally, the temperature dependence of Li diffusion is described by the Arrhenius law. These findings suggest that the stacking structure of BLG has an important influence on Li diffusion within BLG, and changing the stacking structure of BLG is one possible way to greatly improve Li diffusion rate within BLG. At last, it is suggested that AB-stacked BLG can be an excellent candidate for anode material in Lithium-ion batteries., Comment: 11 figures

Published
2019
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