Your search keyword '"Zhang, Qingming"' showing total 728 results

1. Crystalline electric field excitations and their nonlinear splitting under magnetic fields in YbOCl

Author

Cai, Yanzhen, Ren, Wei, Dai, Xijing, Kang, Jing, Zhuo, Weizhen, Xie, Mingtai, Zhang, Anmin, Ji, Jianting, Jin, Feng, Zhang, Zheng, and Zhang, Qingming

Subjects

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

Abstract

Recently reported van der Waals layered honeycomb rare-earth chalcohalides REChX (RE = rare earth, Ch = chalcogen, and X = halogen) are considered to be promising Kitaev spin liquid (KSL) candidates. The high-quality single crystals of YbOCl, a representative member of the family with an effective spin of 1/2, are available now. The crystalline electric field (CEF) excitations in a rare-earth spin system are fundamentally important for understanding both finite-temperature and ground-state magnetism, but remain unexplored in YbOCl so far. In this paper, we conduct a comprehensive Raman scattering study to unambiguously identify the CEF excitations in YbOCl and determine the CEF parameters and wave functions. Our Raman experiments further reveal the anomalous nonlinear CEF splitting under magnetic fields. We have grown single crystals of YbOCl, the nonmagnetic LuOCl, and the diluted magnetic Lu_{0.86}Yb_{0.14}OCl to make a completely comparative investigation. Polarized Raman spectra on the samples at 1.8 K allow us to clearly assign all the Raman-active phonon modes and explicitly identify the CEF excitations in YbOCl. The CEF excitations are further examined using temperature-dependent Raman measurements and careful symmetry analysis based on Raman tensors related to CEF excitations. By applying the CEF Hamiltonian to the experimentally determined CEF excitations, we extract the CEF parameters and eventually determine the CEF wave functions. The study experimentally pins down the CEF excitations in the Kitaev compound YbOCl and sets a foundation for understanding its finite-temperature magnetism and exploring the possible nontrivial spin ground state., Comment: 11 pages, 5 figures

Published

2024

2. Rare-Earth Chalcogenides: An Inspiring Playground For Exploring Frustrated Magnetism

Author

Xie, Mingtai, Zhuo, Wenzhen, Cai, Yanzhen, Zhang, Zheng, and Zhang, Qingming

Subjects

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

Abstract

The rare-earth chalcogenide $ARECh_{2}$ family ($A =$ alkali metal or monovalent ions, $RE =$ rare earth, $Ch =$ chalcogen) has emerged as a paradigmatic platform for studying frustrated magnetism on a triangular lattice. The family members exhibit a variety of ground states, from quantum spin liquid to exotic ordered phases, providing fascinating insight into quantum magnetism. Their simple crystal structure and chemical tunability enable systematic exploration of competing interactions in quantum magnets. Recent neutron scattering and thermodynamic studies have revealed rich phase diagrams and unusual excitations, refining theoretical models of frustrated systems. This review provides a succinct introduction to $ARECh_{2}$ research. It summarizes key findings on crystal structures, single-ion physics, magnetic Hamiltonians, ground states, and low-energy excitations. By highlighting current developments and open questions, we aim to catalyze further exploration and deeper physical understanding on this frontier of quantum magnetism., Comment: 15 pages, 5 figures

Published

2024

3. Ground State Magnetic Structure and Magnetic Field Effects in the Layered Honeycomb Antiferromagnet YbOCl

Author

Zhang, Zheng, Cai, Yanzhen, Jiao, Jinlong, Kang, Jing, Yu, Dehong, Roessli, Bertrand, Zhang, Anmin, Ji, Jianting, Jin, Feng, Ma, Jie, and Zhang, Qingming

Subjects

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

Abstract

YbOCl is a representative member of the van der Waals layered honeycomb rare-earth chalcohalide REChX (RE = rare earth, Ch = O, S, Se, and Te, and X = F, Cl, Br, and I) family reported recently. Its spin ground state remains to be explored experimentally. In this paper, we have grown high-quality single crystals of YbOCl and conducted comprehensive thermodynamic, elastic, and inelastic neutron scattering experiments down to 50 mK. The experiments reveal an antiferromagnetic phase below 1.3 K, which is identified as a spin ground state with an intralayer ferromagnetic and interlayer antiferromagnetic ordering. By applying sophisticated numerical techniques to a honeycomb (nearest-neighbor)-triangle (next-nearest-neighbor) model Hamiltonian which accurately describes the highly anisotropic spin system, we are able to well simulate the experiments and determine the diagonal and off-diagonal spin-exchange interactions. The simulations give an antiferromagnetic Kitaev term comparable to the Heisenberg one. The experiments under magnetic fields allow us to establish a magnetic field-temperature phase diagram around the spin ground state. Most interestingly, a relatively small magnetic field (~ 0.3 to 3 T) can significantly suppress the antiferromagnetic order, suggesting an intriguing interplay of the Kitaev interaction and magnetic fields in the spin system. The present study provides fundamental insights into the highly anisotropic spin systems and opens a new window to look into Kitaev spin physics in a rare-earth-based system., Comment: 9 pages, 4 figures

Published

2024

4. Finite Temperature Magnetism in the Triangular Lattice Antiferromagnet KErTe2

Author

Liu, Weiwei, Zhang, Zheng, Yan, Dayu, Li, Jianshu, Zhang, Zhitao, Ji, Jianting, Jin, Feng, Shi, Youguo, and Zhang, Qingming

Subjects

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

Abstract

After the discovery of the ARECh2 (A=alkali or monovalent ions, RE=rare-earth, Ch= chalcogen) triangular lattice quantum spin liquid (QSL) family, a series of its oxide, sulfide, and selenide counterparts has been consistently reported and extensively investigated. While KErTe2 represents the initial synthesized telluride member, preserving its triangular spin lattice, it was anticipated that the substantial tellurium ions could impart more pronounced magnetic attributes and electronic structures to this material class. This study delves into the magnetism of KErTe2 at finite temperatures through magnetization and electron spin resonance (ESR) measurements. Based on the angular momentum $\hat{J}$ after spin-orbit coupling (SOC) and symmetry analysis, we obtain the magnetic effective Hamiltonian to describe the magnetism of Er3+ in R-3m space group. Applying the mean-field approximation to the Hamiltonian, we can simulate the magnetization and magnetic heat capacity of KErTe2 in paramagnetic state and determine the crystalline electric field (CEF) parameters and partial exchange interactions. The relatively narrow energy gaps between CEF ground state and excited states exert a significant influence on the magnetism. For example, small CEF excitations can result in a significant broadening of the ESR linewidth at 2 K. For the fitted exchange interactions, although the values are small, given a large angular momentum J = 15/2 after SOC, they still have a noticeable effect at finite temperatures. Notably, the heat capacity data under different magnetic fields along the c-axis direction also roughly match our calculated results, further validating the reliability of our analytical approach. These derived parameters serve as crucial tools for future investigations into the ground state magnetism of KErTe2., Comment: 11 pages, 6 figures

Published

2024

5. Spectrum and low-energy gap in triangular quantum spin liquid NaYbSe$_2$

Author

Scheie, A. O., Lee, Minseong, Wang, Kevin, Laurell, P., Choi, E. S., Pajerowski, D., Zhang, Qingming, Ma, Jie, Zhou, H. D., Lee, Sangyun, Thomas, S. M., Ajeesh, M. O., Rosa, P. F. S., Chen, Ao, Zapf, Vivien S., Heyl, M., Batista, C. D., Dagotto, E., Moore, J. E., and Tennant, D. Alan

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We report neutron scattering, pressure-dependent AC calorimetry, and AC magnetic susceptibility measurements of triangular lattice NaYbSe$_2$. We observe a continuum of scattering, which is reproduced by matrix product simulations, and no phase transition is detected in any bulk measurements. Comparison to heat capacity simulations suggest the material is within the Heisenberg spin liquid phase. AC Susceptibility shows a significant 23~mK downturn, indicating a gap in the magnetic spectrum. The combination of a gap with no detectable magnetic order, comparison to theoretical models, and comparison to other $A$YbSe$_2$ compounds all strongly indicate NaYbSe$_2$ is within the quantum spin liquid phase. The gap also allows us to rule out a gapless Dirac spin liquid, with a gapped $\mathbb{Z}_2$ liquid the most natural explanation., Comment: 5 pages, 4 figures; 7 pages and 13 figures supplemental materials

Published

2024

6. Interlayer Fermi polarons of excited exciton states in quantizing magnetic fields

Author

Cui, Huiying, Hu, Qianying, Zhao, Xuan, Ma, Liguo, Jin, Feng, Zhang, Qingming, Watanabe, Kenji, Taniguchi, Takashi, Shan, Jie, Mak, Kin Fai, Li, Yongqing, and Xu, Yang

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The study of exciton-polarons has offered profound insights into the many-body interactions between bosonic excitations and their immersed Fermi sea within layered heterostructures. However, little is known about the properties of exciton polarons with interlayer interactions. Here through magneto-optical reflectance contrast measurements, we experimentally investigate interlayer Fermi polarons for 2s excitons in WSe$_2$/graphene heterostructures, where the excited exciton states (2s) in the WSe$_2$ layer are dressed by free charge carriers of the adjacent graphene layer in the Landau quantization regime. First, such a system enables an optical detection of integer and fractional quantum Hall states (e.g. $\nu=\pm1/3$, $\pm$2/3) of monolayer graphene. Furthermore, we observe that the 2s state evolves into two distinct branches, denoted as attractive and repulsive polarons, when graphene is doped out of the incompressible quantum Hall gaps. Our work paves the way for the understanding of the excited composite quasiparticles and Bose-Fermi mixtures., Comment: 21 pages, 4 figures, and supporting information

Published

2024

7. Magnetism of $\mathrm{NaYbS_2}$: From finite temperatures to ground state

Author

Zhuo, Weizhen, Zhang, Zheng, Xie, Mingtai, Zhang, Anmin, Ji, Jianting, Jin, Feng, and Zhang, Qingming

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Rare-earth chalcogenide compounds $\mathrm{ARECh_2}$ (A = alkali or monovalent metal, RE = rare earth, Ch = O, S, Se, Te) are a large family of quantum spin liquid (QSL) candidate materials. $\mathrm{NaYbS_2}$ is a representative member of the family. Several key issues on $\mathrm{NaYbS_2}$, particularly how to determine the highly anisotropic spin Hamiltonian and describe the magnetism at finite temperatures and the ground state, remain to be addressed. In this paper, we conducted an in-depth and comprehensive study on the magnetism of $\mathrm{NaYbS_2}$ from finite temperatures to the ground state. Firstly, we successfully detected three crystalline electric field (CEF) excitation energy levels using low-temperature Raman scattering technique. Combining them with the CEF theory and magnetization data, we worked out the CEF parameters, CEF energy levels, and CEF wavefunctions. We further determined a characteristic temperature of $\sim$40 K, above which the magnetism is dominated by CEF excitations while below which the spin-exchange interactions play a main role. The characteristic temperature has been confirmed by the temperature-dependent electron spin resonance (ESR) linewidth. Low-temperature ESR experiments on the dilute magnetic doped crystal of $\mathrm{NaYb_{0.1}Lu_{0.9}S_2}$ further helped us to determine the accurate $g$-factor. Next, we quantitatively obtained the spin-exchange interactions in the spin Hamiltonian by consistently simulating the magnetization and specific heat data. Finally, the above studies allow us to explore the ground state magnetism of $\mathrm{NaYbS_2}$ by using the density matrix renormalization group. We combined numerical calculations and experimental results to demonstrate that the ground state of $\mathrm{NaYbS_2}$ is a Dirac-like QSL., Comment: 13 pages, 6 figures

Published

2024

8. van Hove Singularity-Driven Emergence of Multiple Flat Bands in Kagome Superconductors

Author

Luo, Hailan, Zhao, Lin, Zhao, Zhen, Yang, Haitao, Huang, Yun-Peng, Liu, Hongxiong, Gu, Yuhao, Jin, Feng, Chen, Hao, Miao, Taimin, Yin, Chaohui, Shen, Chengmin, Ren, Xiaolin, Liang, Bo, Shu, Yingjie, Chen, Yiwen, Zhang, Fengfeng, Yang, Feng, Zhang, Shenjin, Peng, Qinjun, Mao, Hanqing, Liu, Guodong, Hu, Jiangping, Shi, Youguo, Xu, Zuyan, Jiang, Kun, Zhang, Qingming, Wang, Ziqiang, Gao, Hongjun, and Zhou, X. J.

Subjects

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

Abstract

The newly discovered Kagome superconductors AV$_3$Sb$_5$ (A=K, Rb and Cs) continue to bring surprises in generating unusual phenomena and physical properties, including anomalous Hall effect, unconventional charge density wave, electronic nematicity and time-reversal symmetry breaking. Here we report an unexpected emergence of multiple flat bands in the AV$_3$Sb$_5$ superconductors. By performing high-resolution angle-resolved photoemission (ARPES) measurements, we observed four branches of flat bands that span over the entire momentum space. The appearance of the flat bands is not anticipated from the band structure calculations and cannot be accounted for by the known mechanisms of flat band generation. It is intimately related to the evolution of van Hove singularities. It is for the first time to observe such emergence of multiple flat bands in solid materials. Our findings provide new insights in revealing the underlying mechanism that governs the unusual behaviors in the Kagome superconductors. They also provide a new pathway in producing flat bands and set a platform to study the flat bands related physics., Comment: 20 pages, 4 figures

Published

2024

9. $\pi$ Phase Interlayer Shift and Stacking Fault in the Kagome Superconductor CsV$_3$Sb$_5$

Author

Jin, Feng, Ren, Wei, Tan, Mingshu, Xie, Mingtai, Lu, Bingru, Zhang, Zheng, Ji, Jianting, and Zhang, Qingming

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

The stacking degree of freedom is a crucial factor in tuning material properties and has been extensively investigated in layered materials. The kagome superconductor CsV$_3$Sb$_5$ was recently discovered to exhibit a three-dimensional CDW phase below TCDW ~94 K. Despite the thorough investigation of in-plane modulation, the out-of-plane modulation has remained ambiguous. Here, our polarization- and temperature-dependent Raman measurements reveal the breaking of C$_6$ rotational symmetry and the presence of three distinct domains oriented at approximately 120{\deg}to each other. The observations demonstrate that the CDW phase can be naturally explained as a 2c staggered order phase with adjacent layers exhibiting a relative ${\pi}$ phase shift. Further, we discover a first-order structural phase transition at approximately 65 K and suggest that it is a stacking order-disorder phase transition due to stacking fault, supported by the thermal hysteresis behavior of a Cs-related phonon mode. Our findings highlight the significance of the stacking degree of freedom in CsV$_3$Sb$_5$ and offer structural insights to comprehend the entanglement between superconductivity and CDW., Comment: This manuscript was published in Phys. Rev. Lett

Published

2024

10. Evidence for an Excitonic Insulator State in Ta$_2$Pd$_3$Te$_5$

Author

Huang, Jierui, Jiang, Bei, Yao, Jingyu, Yan, Dayu, Lei, Xincheng, Gao, Jiacheng, Guo, Zhaopeng, Jin, Feng, Li, Yupeng, Yuan, Zhenyu, Chai, Congcong, Sheng, Haohao, Pan, Mojun, Chen, Famin, Liu, Junde, Gao, Shunye, Qu, Gexing, Liu, Bo, Jiang, Zhicheng, Liu, Zhengtai, Ma, Xiaoyan, Zhou, Shiming, Huang, Yaobo, Yun, Chenxia, Zhang, Qingming, Li, Shiliang, Jin, Shifeng, Ding, Hong, Shen, Jie, Su, Dong, Shi, Youguo, Wang, Zhijun, and Qian, Tian

Subjects

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

Abstract

The excitonic insulator (EI) is an exotic ground state of narrow-gap semiconductors and semimetals arising from spontaneous condensation of electron-hole pairs bound by attractive Coulomb interaction. Despite research on EIs dating back to half a century ago, their existence in real materials remains a subject of ongoing debate. In this study, through systematic experimental and theoretical investigations, we provide evidence for the existence of an EI ground state in a van der Waals compound Ta$_2$Pd$_3$Te$_5$. Density-functional-theory calculations suggest that it is a semimetal with a small band overlap, whereas various experiments exhibit an insulating ground state with a clear band gap. Upon incorporating electron-hole Coulomb interaction into our calculations, we obtain an EI phase where the electronic symmetry breaking opens a many-body gap. Angle-resolved photoemission spectroscopy measurements exhibit that the band gap is closed with a significant change in the dispersions as the number of thermally excited charge carriers becomes sufficiently large in both equilibrium and nonequilibrium states. Structural measurements reveal a slight breaking of crystal symmetry with exceptionally small lattice distortion in the insulating state, which cannot account for the significant gap opening. Therefore, we attribute the insulating ground state with a gap opening in Ta$_2$Pd$_3$Te$_5$ to exciton condensation, where the coupling to the symmetry-breaking electronic state induces a subtle change in the crystal structure., Comment: 10 pages, 5 figures

Published

2023

11. Observation of phonon Stark effect

Author

Huang, Zhiheng, Bai, Yunfei, Zhao, Yanchong, Liu, Le, Zhao, Xuan, Wu, Jiangbin, Watanabe, Kenji, Taniguchi, Takashi, Yang, Wei, Shi, Dongxia, Xu, Yang, Zhang, Tiantian, Zhang, Qingming, Tan, Ping-Heng, Sun, Zhipei, Meng, Sheng, Wang, Yaxian, Du, Luojun, and Zhang, Guangyu

Published

2024

12. Observation of Rydberg moir\'e excitons

Author

Hu, Qianying, Zhan, Zhen, Cui, Huiying, Zhang, Yalei, Jin, Feng, Zhao, Xuan, Zhang, Mingjie, Wang, Zhichuan, Zhang, Qingming, Watanabe, Kenji, Taniguchi, Takashi, Cao, Xuewei, Liu, Wu-Ming, Wu, Fengcheng, Yuan, Shengjun, and Xu, Yang

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Rydberg excitons, the solid-state counterparts of Rydberg atoms, have sparked considerable interest in harnessing their quantum application potentials, whereas a major challenge is realizing their spatial confinement and manipulation. Lately, the rise of two-dimensional moir\'e superlattices with highly tunable periodic potentials provides a possible pathway. Here, we experimentally demonstrate this capability through the observation of Rydberg moir\'e excitons (XRM), which are moir\'e trapped Rydberg excitons in monolayer semiconductor WSe2 adjacent to twisted bilayer graphene. In the strong coupling regime, the XRM manifest as multiple energy splittings, pronounced redshift, and narrowed linewidth in the reflectance spectra, highlighting their charge-transfer character where electron-hole separation is enforced by the strongly asymmetric interlayer Coulomb interactions. Our findings pave the way for pursuing novel physics and quantum technology exploitation based on the excitonic Rydberg states., Comment: 24 pages, including 4 figures and 6 supplementary figures

Published

2023

13. Analysis of the factors causing degradation and changes in the colourful pool area of the Huanglong travertine in Sichuan Province, China

Author

Zhou, ZiJian, Wang, FuDong, Zhu, YuYin, He, WuYang, Dong, FaQin, Tang, Shu, Zhang, QingMing, Jiang, LiPing, Huang, GuoQing, Zhao, XueQin, Li, JunHao, Chen, Shi, and Jing, ShengWen

Published

2024

14. Non-linear magnons and exchange Hamiltonians of delafossite proximate quantum spin liquids

Author

Scheie, A. O., Kamiya, Y., Zhang, Hao, Lee, Sangyun, Woods, A. J., Omanakuttan, A. M., Gonzalez, M. G., Bernu, B., Villanova, J. W., Xing, J., Huang, Q., Zhang, Qingming, Ma, Jie, Choi, Eun Sang, Pajerowski, D. M., Zhou, Haidong, Sefat, A. S., Okamoto, S., Berlijn, T., Messio, L., Movshovich, R., Batista, C. D., and Tennant, D. A.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Quantum spin liquids (QSL) are theoretical states of matter with long-range entanglement and exotic quasiparticles. However, they generally elude quantitative theory, rendering their underlying phases mysterious and hampering efforts to identify experimental QSL states. Here we study triangular lattice resonating valence bond QSL candidate materials KYbSe$_2$ and NaYbSe$_2$. We measure the magnon modes in their 1/3 plateau phase, where quantitative theory is tractable, using inelastic neutron scattering and fit them using nonlinear spin wave theory. We also fit the KYbSe$_2$ heat capacity using high temperature series expansion. Both KYbSe$_2$ fits yield the same magnetic Hamiltonian to within uncertainty, confirming previous estimates and showing the Heisenberg $J_2/J_1$ to be an accurate model for these materials. Most importantly, comparing KYbSe$_2$ and NaYbSe$_2$ shows that smaller $A$-site Na$^+$ ion has a larger $J_2/J_1$ ratio. However, hydrostatic pressure applied to KYbSe$_2$ increases the ordering temperature (a result consistent with density functional theory calculations), indicating that pressure decreases $J_2/J_1$. These results show how periodic table and hydrostatic pressure can tune the $A$YbSe$_2$ materials in a controlled way., Comment: 7 pages, 7 figures; 4 pages and 7 additional figures of supplemental information

Published

2022

15. Anisotropic exchange coupling and ground state phase diagram of Kitaev compound YbOCl

Author

Zhang, Zheng, Cai, Yanzhen, Kang, Jing, Ouyang, Zhongwen, Zhang, Zhitao, Zhang, Anmin, Ji, Jianting, Jin, Feng, and Zhang, Qingming

Subjects

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

Abstract

Rare-earth chalcohalide REChX (RE = rare earth; Ch = O, S, Se, Te; X = F, Cl, Br, I) is a newly reported family of Kitaev spin liquid candidates. The family offers a platform where a strong spin-orbit coupling meets a van der Waals layered and undistorted honeycomb spin lattice, which outputs highly anisotropic exchange couplings required by the Kitaev model. YbOCl is the first single crystal of the family we grew, with a size up to ~ 15 mm. We have performed magnetization and high magnetic field electron spin resonance measurements from 2 to 300 K. We develop the mean-field scenario for the anisotropic spin system, with which we are able to well describe the experiments and reliably determine the fundamental parameters. The self-consistent simulations give the anisotropic spin-exchange interactions of $J_{\pm}$ (~ -0.3 K) and $J_{zz}$ (~ 1.6 K), and g factors of $g_{ab}$ (~ 3.4) and $g_{c}$ (~ 2.9). Based on the spin-exchange interactions, we employ the exact diagonalization method to work out the ground state phase diagram of YbOCl in terms of the off-diagonal exchange couplings. The phase diagram hosting rich magnetic phases including the spin-disordered one, sheds light on the novel magnetic properties of the family, particularly the Kitaev physics., Comment: 11 pages, 10 figures

Published

2022

16. Electronic structure and open-orbit Fermi surface topology in isostructural semimetals NbAs$_2$ and W$_2$As$_3$ with extremely large magnetoresistance

Author

Lou, Rui, Wang, Yiyan, Zhao, Lingxiao, Xu, Chenchao, Li, Man, Chen, Xiaoyang, Zhang, Anmin, Huang, Yaobo, Cao, Chao, Chen, Genfu, Xia, Tianlong, Zhang, Qingming, Ding, Hong, and Wang, Shancai

Subjects

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

Abstract

In transition-metal dipnictides $TmPn_2$ ($Tm$ = Ta, Nb; $Pn$ = P, As, Sb), the origin of extremely large magnetoresistance (XMR) is yet to be studied by the direct visualization of the experimental band structures. Here, using angle-resolved photoemission spectroscopy, we map out the three-dimensional electronic structure of NbAs$_2$. The open-orbit topology contributes to a non-negligible part of the Fermi surfaces (FSs), like that of the isostructural compound MoAs$_2$, where the open FS is proposed to likely explain the origin of XMR. We further demonstrate the observation of open characters in the overall FSs of W$_2$As$_3$, which is also a XMR semimetal with the same space group of $C$12/$m$1 as $TmPn_2$ family and MoAs$_2$. Our results suggest that the open-orbit FS topology may be a shared feature between XMR materials with the space group of $C$12/$m$1, and thus could possibly play a role in determining the corresponding XMR effect together with the electron-hole compensation., Comment: 7 pages, 4 figures, Editor's pick

Published

2022

17. High-efficient removal of tebuconazole from aqueous solutions using P-doped corn straw biochar: Performance, mechanism and application

Author

Xu, Congling, Wang, Yanhui, Ma, Xiaoxia, Wang, Xiaoyu, Yang, Yong, and Zhang, Qingming

Published

2024

18. Ejecta velocity and motion model of spherical aluminum alloy projectile hypervelocity impact on basalt

Author

Liu, Wenjin, Zhang, Qingming, Long, Renrong, Gong, Zizheng, Wu, Qiang, Siyuan, Ren, Lu, Yangyu, Xu, Jinlong, Zhong, Xianzhe, and Jiankang, Ren

Published

2024

19. Type Id versus type IId three-level hybrid surgery for the treatment of noncontiguous cervical spondylosis: A finite element analysis

Author

Huang, Jiang, Sun, Xiangyao, Zhang, Qingming, Cao, Li, Liu, Yuqi, Song, Zelong, Tang, Wei, Sun, Siyuan, and Wang, Juyong

Published

2024

20. Combination of the degrading bacterium Bacillus cereus MZ-1 and corn straw biochar enhanced the removal of imazethapyr from water solutions

Author

Miao, Jingbo, Fan, Qingqing, Li, Hao, Yang, Yong, and Zhang, Qingming

Published

2025

21. Low-energy Spin Dynamics of Quantum Spin Liquid Candidate $NaYbSe_{2}$

Author

Zhang, Zheng, Li, Jianshu, Xie, Mingtai, Zhuo, Weizhen, Adroja, D. T., Baker, Peter J., Perring, T. G., Zhang, Anmin, Jin, Feng, Ji, Jianting, Wang, Xiaoqun, Ma, Jie, and Zhang, Qingming

Subjects

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

Abstract

The family of rare earth chalcogenides $ARECh_{2}$ (A = alkali or monovalent ions, RE = rare earth, and Ch = O, S, Se, and Te) appears as an inspiring playground for studying quantum spin liquids (QSL). The crucial low-energy spin dynamics remain to be uncovered. By employing muon spin relaxation ($\mu$SR) and zero-field (ZF) AC susceptibility down to 50 mK, we are able to identify the gapless QSL in $NaYbSe_{2}$, a representative member with an effective spin-1/2, and explore its unusual spin dynamics. The ZF $\mu$SR experiments unambiguously rule out spin ordering or freezing in $NaYbSe_{2}$ down to 50 mK, two orders of magnitude smaller than the exchange coupling energies. The spin relaxation rate, $\lambda$, approaches a constant below 0.3 K, indicating finite spin excitations featured by a gapless QSL ground state. This is consistently supported by our AC susceptibility measurements. The careful analysis of the longitudinal field (LF) $\mu$SR spectra reveals a strong spatial correlation and a temporal correlation in the spin-disordered ground state, highlighting the unique feature of spin entanglement in the QSL state. The observations allow us to establish an experimental H-T phase diagram. The study offers insight into the rich and exotic magnetism of the rare earth family., Comment: 21 pages, 18 figures

Published

2021

22. Dynamic mechanical response and constitutive model of (Ti37.31Zr22.75Be26.39Al4.55Cu9)94Co6 high-entropy bulk metallic glass

Author

Zhong, Xianzhe, Zhang, Qingming, Ma, Mingzhen, Xie, Jing, Wu, Mingze, and Ren, Jiankang

Published

2024

23. Biomechanical effects of hybrid constructions in the treatment of noncontinuous cervical spondylopathy: a finite element analysis

Author

Sun, Xiangyao, Zhang, Qingming, Cao, Li, Wang, Juyong, Huang, Jiang, Liu, Yuqi, Zhang, Yang, Song, Zelong, Tang, Wei, Chen, Yunqiang, Sun, Siyuan, and Lu, Shibao

Published

2023

24. Effects of the Crystalline Electric Field in the $KErTe_{2}$ Quantum Spin Liquid Candidate

Author

Liu, Weiwei, Zhang, Zheng, Yan, Dayu, Li, Jianshu, Zhang, Zhitao, Ji, Jianting, Jin, Feng, Shi, Youguo, and Zhang, Qingming

Subjects

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

Abstract

In this paper, we performed thermodynamic and electron spin resonance (ESR) measurements to study low-energy magnetic excitations, which were significantly affected by crystalline electric field (CEF) excitations due to relatively small gaps between the CEF ground state and the excited states. Based on the CEF and mean-field (MF) theories, we analyzed systematically and consistently the ESR experiments and thermodynamic measurements including susceptibility, magnetization, and heat capacity. The CEF parameters were successfully extracted by fitting high-temperature (> 20 K) susceptibilities in the ab-plane and along the c-axis, allowing to determine the Lande factors ($g_{ab,calc}$ = 5.98(7) and $g_{c,calc}$ = 2.73(3)). These values were consistent with the values of Lande factors determined by ESR experiments ($g_{ab,exp}$ = 5.69 and $g_{c,exp}$ = 2.75). By applying the CEF and MF theories to the susceptibility and magnetization results, we estimated the anisotropic spin-exchange energies and found that the CEF excitations in \ce{KErTe2} played a decisive role in the magnetism above 3 K, while the low-temperature magnetism below 10 K was gradually correlated with the anisotropic spin-exchange interactions. The CEF excitations were demonstrated in the low-temperature heat capacity, where both the positions of two broad peaks and their magnetic field dependence well corroborated our calculations. The present study provides a basis to explore the enriched magnetic and electronic properties of the QSL family., Comment: 9 pages, 5 figures

Published

2021

25. Comparative uptake, translocation and metabolism of phenamacril in crops under hydroponic and soil cultivation conditions

Author

Chang, Jinhe, Gao, Kang, Li, Runan, Dong, Fengshou, Zheng, Yongquan, Zhang, Qingming, and Li, Yuanbo

Published

2024

26. Energy distribution characteristic of impact flash of metallic target impacted by hypersonic projectile

Author

Xue, Yijiang, Zhang, Qingming, Hao, Wei, and Wang, Weihua

Published

2024

27. An expansion model of hypervelocity impact-generated plasma aided by spectral methods

Author

Wang, Jie, Gong, Liangfei, Long, Renrong, Chen, Li, Wu, Qiang, Ren, Siyuan, Xue, Yijiang, and Zhang, Qingming

Published

2024

28. Two-magnon Raman scattering in antiferromagnetic phases of frustrated spin models on the honeycomb lattice

Author

Pan, Junru, Jin, Feng, Ji, Jianting, Zhang, Qingming, and Yu, Rong

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We calculate the two-magnon Raman scattering spectra in antiferromagnetic phases of several frustrated spin models defined on the honeycomb lattice. These include the N\'{e}el antiferromagnetic phase of a $J_1$-$J_2$-$J_3$ model and the stripe phase of the Heisenberg-Kitaev model. We show that both the magnetic frustration and the anisotropy of interactions may significantly affect the Raman spectra. We further discuss the implications of our results to the magnetic excitations of the iron-based compound BaFe$_2$Se$_2$O and show how the magnetic interactions can be extracted from fit to the Raman spectrum., Comment: 6 pages, 5 figures

Published

2021

29. Effective Model for Rare-earth Kitaev Materials and its Classical Monte Carlo Simulation

Author

Sun, Mengjie, Lin, Huihang, Zhang, Zheng, Cai, Yanzhen, Ren, Wei, Kang, Jing, Ji, Jianting, Jin, Feng, Wang, Xiaoqun, Yu, Rong, Zhang, Qingming, and Liu, Zhengxin

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Recently, the family of rare-earth chalcohalides were proposed as candidate compounds to realize the Kitaev spin liquid (KSL). In the present work, we firstly propose an effective spin Hamiltonian consistents with the symmetry group of the crystal structure. Then we apply classical Monte Carlo simulations to preliminarily study the model and establish a phase diagram. When approaching to the low temperature limit, several magnetic long range orders are observed, including the stripe, the zigzag, the antiferromagnetic (AFM), the ferromagnetic (FM), the incommensurate spiral (IS), the Multi-$\pmb {Q}$ and the 120{\deg}. We further calculate the thermodynamic properties of the system, such as the temperature dependence of the magnetic susceptibility and the heat capacity. The ordering transition temperatures reflected in the two quantities agree with each other. For most interaction regions, the system is magnetically more susceptible in the $ab$-plane than in the $c$-direction. The stripe phase is special, where the susceptibility is fairly isotropic in the whole temperature region. These features provide useful information to understand the magnetic properties of related materials.

Published

2021

30. Rare-earth chalcohalides: A family of van der Waals layered Kitaev spin liquid candidates

Author

Ji, Jianting, Sun, Mengjie, Cai, Yanzhen, Wang, Yimeng, Sun, Yingqi, Ren, Wei, Zhang, Zheng, Jin, Feng, and Zhang, Qingming

Subjects

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

Abstract

Kitaev spin liquid (KSL) system has attracted tremendous attention in past years because of its fundamental significance in condensed matter physics and promising applications in fault-tolerant topological quantum computation. Material realization of such a system remains a major challenge in the field due to the unusual configuration of anisotropic spin interactions, though great effort has been made before. Here we reveal that rare-earth chalcohalides REChX (RE=rare earth, Ch=O, S, Se, Te, X=F, Cl, Br, I) can serve as a family of KSL candidates. Most family members have the typical SmSI-type structure with a high symmetry of R-3m and rare-earth magnetic ions form an undistorted honeycomb lattice. The strong spin-orbit coupling of 4f electrons intrinsically offers anisotropic spin interactions as required by Kitaev model. We have grown the crystals of YbOCl and synthesized the polycrystals of SmSI, ErOF, HoOF and DyOF, and made careful structural characterizations. We carry out magnetic and heat capacity measurements down to 1.8 K and find no obvious magnetic transition in all the samples but DyOF. The van der Waals interlayer coupling highlights the true two-dimensionality of the family which is vital for the exact realization of Abelian/non-Abelian anyons, and the graphene-like feature will be a prominent advantage for developing miniaturized devices. The family is expected to act as an inspiring material platform for the exploration of KSL physics., Comment: 6 pages, 6 figures, 2 tables

Published

2021

31. Effects of projectile parameters on the momentum transfer and projectile melting during hypervelocity impact

Author

Liu, Wenjin, Zhang, Qingming, Long, Renrong, Gong, Zizheng, Jiankang, Ren, Hu, Xin, Ren, Siyuan, Wu, Qiang, and Song, Guangming

Published

2024

32. Review of bumper materials for spacecraft shield against orbital debris hypervelocity impact

Author

Ren, Siyuan, Zhang, Pinliang, Wu, Qiang, Zhang, Qingming, Gong, Zizheng, Song, Guangming, Long, Renrong, Gong, Liangfei, and Wu, Mingze

Published

2024

33. Effective Magnetic Hamiltonian at Finite Temperatures for Rare Earth Chalcogenides

Author

Zhang, Zheng, Li, Jianshu, Liu, Weiwei, Zhang, Zhitao, Ji, Jianting, Jin, Feng, Chen, Rui, Wang, Junfeng, Wang, Xiaoqun, Ma, Jie, and Zhang, Qingming

Subjects

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

Abstract

Alkali metal rare-earth chalcogenide $ARECh2$ (A=alkali or monovalent metal, RE=rare earth, Ch=O, S, Se, Te), is a large family of quantum spin liquid (QSL) candidates we discovered recently. Unlike $YbMgGaO4$, most members in the family except for the oxide ones, have relatively small crystalline electric-field (CEF) excitation levels, particularly the first ones. This makes the conventional Curie-Weiss analysis at finite temperatures inapplicable and CEF excitations may play an essential role in understanding the low-energy spin physics. Here we considered an effective magnetic Hamiltonian incorporating CEF excitations and spin-spin interactions, to accurately describe thermodynamics in such a system. By taking $NaYbSe2$ as an example, we were able to analyze magnetic susceptibility, magnetization under pulsed high fields and heat capacity in a systematic and comprehensive way. The analysis allows us to produce accurate anisotropic exchange coupling energies and unambiguously determine a crossover temperature ($\sim$25 K in the case of $NaYbSe2$), below which CEF effects fade away and pure spin-spin interactions stand out. We further validated the effective picture by successfully explaining the anomalous temperature dependence of electron spin resonance (ESR) spectral width. The effective scenario in principle can be generalized to other rare-earth spin systems with small CEF excitations., Comment: 7 pages, 4 figures + Supplementary Information

Published

2020

34. Dimensional Crossover Tuned by Pressure in Layered Magnetic NiPS3

Author

Ma, Xiaoli, Wang, Yimeng, Yin, Yunyu, Yue, Binbin, Dai, Jianhong, Ji, Jianting, Jin, Feng, Hong, Fang, Wang, Jian-Tao, Zhang, Qingming, and Yu, Xiaohui

Subjects

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

Abstract

Layered magnetic transition-metal thiophosphate NiPS3 has unique two-dimensional (2D) magnetic properties and electronic behavior. The electronic band structure and corresponding magnetic state are expected to sensitive to the interlayer interaction, which can be tuned by external pressure. Here, we report an insulator-metal transition accompanied with magnetism collapse during the 2D-3D crossover in structure induced by hydrostatic pressure. A two-stage phase transition from monoclinic (C2=m) to trigonal (P-31m) lattice is identified by ab initio simulation and confirmed by high-pressure XRD and Raman data, corresponding to a layer by layer slip mechanism along the a-axis. Temperature dependence resistance measurements and room temperature infrared spectroscopy show that the insulator-metal transition occurs near 20 GPa as well as magnetism collapse, which is further confirmed by low temperature Raman measurement and theoretical calculation. These results establish a strong correlation among the structural change, electric transport, and magnetic phase transition and expand our understandings about the layered magnetic materials., Comment: 8 pages, 5 figures

Published

2020

35. Field evolution of the spin-liquid candidate YbMgGaO$_4$

Author

Bachus, Sebastian, Iakovlev, Ilia A., Li, Yuesheng, Wörl, Andreas, Tokiwa, Yoshifumi, Ling, Langsheng, Zhang, Qingming, Mazurenko, Vladimir V., Gegenwart, Philipp, and Tsirlin, Alexander A.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We report magnetization, heat capacity, thermal expansion, and magnetostriction measurements down to millikelvin temperatures on the triangular antiferromagnet YbMgGaO$_4$. Our data exclude the formation of the distinct $\frac13$ plateau phase observed in other triangular antiferromagnets, but reveal plateaulike features in second derivatives of the free energy, magnetic susceptibility and specific heat, at $\mu_0H$ = 1.0 - 2.5 T for $H\parallel{}c$ and 2 - 5 T for $H\perp{}c$. Using Monte-Carlo simulations of a realistic spin Hamiltonian, we ascribe these features to nonmonotonic changes in the magnetization and the $\frac12$ plateau that is smeared out by the random distribution of exchange couplings in YbMgGaO$_4$.

Published

2020

36. Pressure induced metallization and possible unconventional superconductivity in spin liquid $NaYbSe_{2}$

Author

Zhang, Zheng, Yin, Yunyu, Ma, Xiaoli, Liu, Weiwei, Li, Jianshu, Jin, Feng, Ji, Jianting, Wang, Yimeng, Wang, Xiaoqun, Yu, Xiaohui, and Zhang, Qingming

Subjects

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

Abstract

Beyond the conventional electron pairing mediated by phonons, high-temperature superconductivity in cuprates is believed to stem from quantum spin liquid (QSL). The unconventional superconductivity by doping a spin liquid/Mott insulator, is a long-sought goal but a principal challenge in condensed matter physics because of the lack of an ideal QSL platform. Here we report the pressure induced metallization and possible unconventional superconductivity in $NaYbSe_{2}$, which belongs to a large and ideal family of triangular lattice spin liquid we revealed recently and is evidenced to possess a QSL ground state. The charge gap of NaYbSe2 is gradually reduced by applying pressures, and at ~20 GPa the crystal jumps into a superconducting (SC) phase with Tc ~ 5.8 K even before the insulating gap is completely closed. The metallization is confirmed by further high-pressure experiments but the sign of superconductivity is not well repeated. No symmetry breaking accompanies the SC transition, as indicated by X-ray diffraction and low-temperature Raman experiments under high pressures. This intrinsically connects QSL and SC phases, and suggests an unconventional superconductivity developed from QSL. We further observed the magnetic-field-tuned superconductor-insulator transition which is analogous to that found in the underdoped cuprate superconductor $La_{2-x}Sr_{x}CuO_{4}$. The study is expected to inspire interest in exploring new types of superconductors and sheds light into the intriguing physics from a spin liquid/Mott insulator to a superconductor., Comment: 15 pages, 5 figures

Published

2020

37. Magnetic field effects on the quantum spin liquid behaviors of NaYbS$_2$

Author

Wu, Jiangtao, Li, Jianshu, Zhang, Zheng, Liu, Changle, Gao, YongHao, Feng, Erxi, Deng, Guochu, Ren, Qingyong, Wang, Zhe, Chen, Rui, Embs, Jan, Zhu, Fengfeng, Huang, Qing, Xiang, Ziji, Chen, Lu, Wu, Yan, Choi, E. S., Qu, Zhe, Li, Lu, Wang, Junfeng, Zhou, Haidong, Su, Yixi, Wang, Xiaoqun, Chen, Gang, Zhang, Qingming, and Ma, Jie

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Spin-orbit coupling is an important ingredient to regulate the many-body physics, especially for many spin liquid candidate materials such as rare-earth magnets and Kitaev materials. The rare-earth chalcogenides NaYbCh$_2$ (Ch = O, S, Se) is a congenital frustrating system to exhibit the intrinsic landmark of spin liquid by eliminating both the site disorders between Na$^{+}$ and Yb$^{3+}$ ions with the big ionic size difference and the Dzyaloshinskii-Moriya interaction with the perfect triangular lattice of the Yb$^{3+}$ ions. The temperature versus magnetic-field phase diagram is established by the magnetization, specific heat, and neutron-scattering measurements. Notably, the neutron diffraction spectra and the magnetization curve might provide microscopic evidence for a series of spin configuration for in-plane fields, which include the disordered spin liquid state, 120$^{o}$ antiferromagnet, and one-half magnetization state. Furthermore, the ground state is suggested to be a gapless spin liquid from inelastic neutron scattering, and the magnetic field adjusts the spin orbit coupling. Therefore, the strong spin-orbit coupling in the frustrated quantum magnet substantially enriches low-energy spin physics. This rare-earth family could offer a good platform for exploring the quantum spin liquid ground state and quantum magnetic transitions.

Published

2020

38. Crystalline Electric-Field Excitations in Quantum Spin Liquids Candidate $NaYbSe_{2}$

Author

Zhang, Zheng, Ma, Xiaoli, Li, Jianshu, Wang, Guohua, Adroja, D. T., Perring, T. G., Liu, Weiwei, Jin, Feng, Ji, Jianting, Wang, Yimeng, Wang, Xiaoqun, Ma, Jie, and Zhang, Qingming

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Very recently we revealed a large family of triangular lattice quantum spin liquid candidates named rare-earth chalcogenides, which features a high-symmetry structure without structural/charge disorders and spin impurities, and may serve as an ideal platform exploring spin liquid physics. The knowledge of crystalline electric-field (CEF) excitations is an essential step to explore the fundamental magnetism of rare-earth spin systems. Here we employed inelastic neutron scattering (INS) and Raman scattering (RS) to carry out a comprehensive CFE investigation on $NaYbSe_{2}$, a promising representative of the family. By comparison with its nonmagnetic compound $NaLuSe_{2}$, we are able to identify the CEF excitations at 15.8, 24.3 and 30.5 meV at 5K. The selected cuts of the INS spectra are well re-produced with a large anisotropy of $g$ factors ($g_{ab}:g_{c}\sim3:1$). Further, the CEF excitations are explained well by our calculations based on the point charge model. Interestingly, $NaYbSe_{2}$ exhibits an unusual CEF shift to higher energies with increasing temperatures, and the Raman mode close to the first CEF excitation shows an anomalously large softening with decreasing temperatures. The absence of the anomalies in $NaLuSe_{2}$ clearly demonstrates a CEF-phonon coupling not reported in the family. It can be understood in term of the weaker electronegativity of Se. The fact that the smallest first CEF excitation in the sub-family of $NaYbCh_{2}$ is $\sim$ 180K (Ch=O, S, Se), guarantees that the sub-family can be strictly described with an effective S=1/2 picture at sufficiently low temperatures. Interestingly the CEF-phonon coupling revealed here may present alternative possibilities to manipulate the spin systems., Comment: 7 pages, 4 figures, supplementary material provided, error corrected in Figure 4

Published

2020

39. Experimental and theoretical study on cavitation of concrete targets penetrated by hypervelocity long rod projectiles

Author

Lu, Yangyu, Xue, Yijiang, Zhang, Qingming, Shang, Cheng, and Liu, Wenjin

Published

2023

40. Study on the deformation of inter-rib shell plate of reinforced conical shell structure under deep-water-explosion loading

Author

Xu, Jinlong, Zhang, Qingming, Long, Renrong, and Liang, Haozhe

Published

2023

41. Mechanical behaviors and microstructure evolution of Ni[sbnd]W medium heavy alloy at various strain rates under uniaxial tension

Author

Wu, Haijun, Wang, Kehui, Duan, Jian, Li, Ming, Dai, Xianghui, Zhou, Gang, Wang, Cunxian, Zhao, Feng, and Zhang, Qingming

Published

2023

42. Topological phase transition between distinctWeyl semimetal states in MoTe2

Author

Zhang, Anmin, Ma, Xiaoli, Liu, Changle, Lou, Rui, Wang, Yimeng, Yu, Qiaohe, Wang, Yiyan, Xia, Tian-long, Wang, Shancai, Zhang, Lei, Wang, Xiaoqun, Chen, Changfeng, and Zhang, Qingming

Subjects

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

Abstract

We present experimental evidence of an intriguing phase transition between distinct topological states in the type-II Weyl semimetal MoTe2. We observe anomalies in the Raman phonon frequencies and linewidths as well as electronic quasielastic peaks around 70 K, which, together with structural, thermodynamic measurements, and electron-phonon coupling calculations, demonstrate a temperature-induced transition between two topological phases previously identified by contrasting spectroscopic measurements. An analysis of experimental data suggests electron-phonon coupling as the main driving mechanism for the change of key topological characters in the electronic structure of MoTe2.We also find the phase transition to be sensitive to sample conditions distinguished by synthesis methods. These discoveries of temperature and material condition-dependent topological phase evolutions and transitions in MoTe2 advance the fundamental understanding of the underlying physics and enable an effective approach to tuning Weyl semimetal states for technological applications., Comment: 6 pages, 4 figures

Published

2019

43. Probing the direct factor for superconductivity in FeSe-Based Superconductors by Raman Scattering

Author

Zhang, Anmin, Ma, Xiaoli, Wang, Yimeng, Sun, Shanshan, Lei, Bin, Lei, Hechang, Chen, Xianhui, Wang, Xiaoqun, Chen, Changfeng, and Zhang, Qingming

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

The FeSe-based superconductors exhibit a wide range of critical temperature Tc under a variety of material and physical conditions, but extensive studies to date have yet to produce a consensus view on the underlying mechanism. Here we report on a systematic Raman scattering work on intercalated FeSe superconductors Lix(NH3)yFe2Se2 and (Li,Fe)OHFeSe compared to pristine FeSe. All three crystals show an anomalous power-law temperature dependence of phonon linewidths, deviating from the standard anharmonic behavior. This intriguing phenomenon is attributed to electron-phonon coupling effects enhanced by electron correlation, as evidenced by the evolution of the A1g Raman mode. Meanwhile, an analysis of the B1g mode, which probes the out-of-plane vibration of Fe, reveals a lack of influence by previously suggested structural parameters, and instead indicates a crucial role of the joint density of states in determining Tc. These findings identify carrier doping as the direct factor driving and modulating superconductivity in FeSe-based compounds., Comment: 6 pages, 4 figures

Published

2019

44. Experimental identification of electric dipoles induced by magnetic monopoles in Tb2Ti2O7

Author

Jin, Feng, Liu, Changle, Zhang, Anmin, Wang, Xiaoqun, Chen, Gang, Sun, Xuefeng, and Zhang, Qingming

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The fundamental principles of electrodynamics allow an electron carrying both electric monopole (charge) and magnetic dipole (spin) but prohibit its magnetic counterpart. Recently it was predicted that the magnetic "monopoles" carrying emergent magnetic charges in spin ice systems can induce electric dipoles. The inspiring prediction offers a novel way to study magnetic monopole excitations and magnetoelectric coupling. However, no clear example has been identified up to now. Here, we report the experimental evidence for electric dipoles induced by magnetic monopoles in spin frustrated Tb2Ti2O7. The magnetic field applied to pyrochlore Tb2Ti2O7 along [111] direction, brings out a "3-in-1-out" magnetic monopole configuration, and then induces a subtle structural phase transition at Hc~2.3 T. The transition is evidenced by the non-linear phonon splitting under magnetic fields and the anomalous crystal-field excitations of Tb3+ ions. The observations consistently point to the displacement of the oxygen O" anions along [111] axis which gives rise to the formation of electric dipoles. The finding demonstrates that the scenario of magnetic monopole having both magnetic charge and electric dipole is realized in Tb2Ti2O7 and sheds light into the coupling between electricity and magnetism of magnetic monopoles in spin frustrated systems.

Published

2019

45. Measurement of the neutron beam profile of the Back-n white neutron facility at CSNS with a Micromegas detector

Author

Qi, Binbin, Li, Yang, Zhu, Danyang, Zhang, Zhiyong, Fan, Ruirui, Pan, Jiang, Feng, Jianxin, Liu, Chengming, Feng, Changqing, Liu, Jianbei, Shao, Ming, Zhou, Yi, Wang, Yanfeng, Yi, Han, An, Qi, Bai, Huaiyong, Bao, Jie, Cao, Ping, Chen, Qiping, Chen, Yonghao, Cheng, Pinjing, Cui, Zengqi, Gu, Minhao, Guo, Fengqin, Han, Changcai, Han, Zijie, He, Guozhu, He, Yongcheng, He, Yuefeng, Huang, Hanxiong, Huang, Weiling, Huang, Xiru, Ji, Xiaolu, Ji, Xuyang, Jiang, Haoyu, Jiang, Wei, Jing, Hantao, Kang, Ling, Kang, Mingtao, Li, Bo, Li, Lun, Li, Qiang, Li, Xiao, Liu, Rong, Liu, Shubin, Liu, Xingyan, Luan, Guangyuan, Ma, Yinglin, Ning, Changjun, Ren, Jie, Ruan, Xichao, Song, Zhaohui, Sun, Hong, Sun, Xiaoyang, Sun, Zhijia, Tan, Zhixin, Tang, Hongqing, Tang, Jingyu, Wang, Pengcheng, Wang, Qi, Wang, Taofeng, Wang, Zhaohui, Wang, Zheng, Wen, Jie, Wen, Zhongwei, Wu, Qingbiao, Wu, Xiaoguang, Wu, Xuan, Xie, Likun, Yang, Yiwei, Yu, Li, Yu, Tao, Yu, Yongji, Zhang, Guohui, Zhang, Jing, Zhang, Linhao, Zhang, Liying, Zhang, Qingming, Zhang, Qiwei, Zhang, Xianpeng, Zhang, Yuliang, Zhao, Yingtan, Zhou, Liang, Zhou, Zuying, Zhu, Kejun, and Zhu, Peng

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The Back-n white neutron beam line, which uses back-streaming white neutrons from the spallation target of the China Spallation Neutron Source, is used for nuclear data measurements. A Micromegas-based neutron detector with two variants was specially developed to measure the beam spot distribution for this beam line. In this article, the design, fabrication, and characterization of the detector are described. The results of the detector performance tests are presented, which include the relative electron transparency, the gain and the gain uniformity, and the neutron beam profile reconstruction capability. The result of the first measurement of the Back-n neutron beam spot distribution is also presented., Comment: 31 pages, 18 figures

Published

2019

46. Effects of gradient nanostructures on the tribological properties and projectile abrasion during high-speed penetration in AerMet100 steel

Author

Wu, Haijun, Wang, Kehui, Yang, Hui, Shen, Zikai, Cai, Song, Lan, Shuang, Li, Xiuyan, Zhang, Dongya, Zhou, Gang, and Zhang, Qingming

Published

2023

47. ZIF-8 and humic acid modified magnetic corn stalk biochar: An efficient, magnetically stable, and eco-friendly adsorbent for imidacloprid and thiamethoxam removal

Author

Yang, Yong, Ma, Xinxin, Li, Zifen, Wang, Yanru, Ju, Chao, Cao, Lidong, Zheng, Yongquan, and Zhang, Qingming

Published

2023

48. Mechanical properties and non-isothermal crystallization kinetics of novel Ti-based high-entropy bulk metallic glasses

Author

Zhong, Xianzhe, Zhang, Qingming, Ma, Mingzhen, Xie, Jing, Wu, Mingze, Yan, Yongming, Ren, Siyuan, and Liu, Bowen

Published

2023

49. The Parallelization and Optimization of K-means Algorithm Based on MGPUSim

Author

Mo, Zhangbin, Wang, Yaobin, Zhang, Qingming, Zhang, Guangbing, Guo, Mingfeng, Zhang, Yaqing, Shen, Chao, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Pimenidis, Elias, editor, Angelov, Plamen, editor, Jayne, Chrisina, editor, Papaleonidas, Antonios, editor, and Aydin, Mehmet, editor

Published

2022

50. Experimental study on leakage and diffusion of full-scale buried natural gas pipelines

Author

Li, He, primary, Li, Wenwei, additional, Feng, Hui, additional, Chen, Li, additional, Ma, Xiaohe, additional, Long, Renrong, additional, Zhang, Zheju, additional, Zhang, Qingming, additional, and Wu, Mingze, additional

Published

2022