Your search keyword '"Gong, Ben-Chao"' showing total 39 results

1. Exploring charge and spin fluctuations in infinite-layer cuprate SrCuO$_{2}$ from a phonon perspective

Author

Du, Xin, Sun, Pei-Han, Gong, Ben-Chao, Zhang, Jian-Feng, Lu, Zhong-Yi, and Liu, Kai

Subjects

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

Abstract

The infinite-layer cuprate $A$CuO$_2$ ($A=$ Ca, Sr, Ba) has the simplest crystal structure among numerous cuprate superconductors and can serve a prototypical system to explore the unconventional superconductivity. Based on the first-principles electronic structure calculations, we have studied the electronic and magnetic properties of the infinite-layer cuprate SrCuO$_{2}$ from a phonon perspective. We find that interesting fluctuations of charges, electrical dipoles, and local magnetic moments can be induced by the zero-point vibrations of phonon modes in SrCuO$_{2}$ upon the hole doping. Among all optical phonon modes of SrCuO$_{2}$ in the antiferromagnetic N\'{e}el state, only the $A_{1}$$_g$ mode that involves the full-breathing O vibrations along the Cu-O bonds can cause significant fluctuations of local magnetic moments on O atoms and dramatic charge redistributions between Cu and O atoms. Notably, due to the zero-point vibration of the $A_{1g}$ mode, both the charge fluctuations on Cu and the electrical dipoles on O show a dome-like evolution with increasing hole doping, quite similar to the experimentally observed behavior of the superconducting $T_c$; in comparison, the fluctuations of local magnetic moments on O display a monotonic enhancement along with the hole doping. Further analyses indicate that around the optimal doping, there exist a large softening in the frequency of the $A_{1g}$ phonon mode and a van Hove singularity in the electronic structure close to the Fermi level, suggesting potential electron-phonon coupling. Our work reveals the important role of the full-breathing O phonon mode playing in the infinite-layer SrCuO$_{2}$, which may provide new insights in understanding the cuprate superconductivity., Comment: 7 pages, 4 figures, 1 table

Published

2023

2. Exploring charge and spin fluctuations in infinite-layer cuprate SrCuO2 from a phonon perspective

Author

Du, Xin, Sun, Pei-Han, Gong, Ben-Chao, Zhang, Jian-Feng, Lu, Zhong-Yi, and Liu, Kai

Published

2024

3. Intrinsic ferromagnetic axion states and a single pair of Weyl fermions in the stable-state Mn\emph{X}$_{2}$\emph{B}$_{2}$\emph{T}$_{6}$-family materials

Author

Gao, Yan, Wu, Weikang, Gong, Ben-Chao, Yang, Huan-Cheng, Zhou, Xiang-Feng, Liu, Yong, Yang, Shengyuan A., Liu, Kai, and Lu, Zhong-Yi

Subjects

Condensed Matter - Materials Science

Abstract

The intrinsic ferromagnetic (FM) axion insulators and Weyl semimetals (WSMs) with only single pair of Weyl points have drawn intensive attention but so far remain rare and elusive in real materials. Here, we propose a new class of Mn\emph{X}$_{2}$\emph{B}$_{2}$\emph{T}$_{6}$-B (\emph{X}=Ge, Sn, or Pb; \emph{B}=Sb or Bi; \emph{T}=Se or Te) family that is the stable structural form of this system. We find that the Mn\emph{X}$_{2}$\emph{B}$_{2}$\emph{T}$_{6}$-B family has not only the intrinsic FM axion insulators MnGe$_{2}$Bi$_{2}$Te$_{6}$-B, MnSn$_{2}$Bi$_{2}$Te$_{6}$-B, and MnPb$_{2}$Bi$_{2}$Te$_{6}$-B, but also the intrinsic WSM MnSn$_{2}$Sb$_{2}$Te$_{6}$-B with only a single pair of Weyl points. Thus, the Mn\emph{X}$_{2}$\emph{B}$_{2}$\emph{T}$_{6}$-B family can provide an ideal platform to explore the exotic topological magnetoelectric effect and the intrinsic properties related to Weyl points., Comment: 6 pages, 5 figures

Published

2022

4. Evolution of ultra-flat band in van der Waals kagome semiconductor Pd$_{3}$P$_{2}$(S$_{1-x}$Se$_{x}$)$_{8}$

Author

Yan, Shaohua, Gong, Ben-Chao, Wang, Lin, Wu, Jinzhi, Yin, Qiangwei, Cao, Xinyu, Zhang, Xiao, Liu, Xiaofeng, Lu, Zhong-Yi, Liu, Kai, and Lei, Hechang

Subjects

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

Abstract

We investigate the evolutions of structural parameters, optical properties, and electronic structures of a van der Waals kagome semiconductor Pd$_{3}$P$_{2}$S$_{8}$ with Se doping. When the doping level of Se increases, the bandgaps of Pd$_{3}$P$_{2}$(S$_{1-x}$Se$_{x}$)$_{8}$ single crystals decrease gradually, accompanying with the expanded unit cells. The first-principles calculations show that there is a flat band (FB) near the Fermi level in bulk Pd$_{3}$P$_{2}$S$_{8}$. This FB mainly originates from the $d_{z^2}$-like orbitals of Pd atoms in the Pd kagome lattice, which have a finite interlayer electron hopping perpendicular to the PdS$_4$ square plane. The interlayer hopping can be reinforced with Se doping, inducing a stronger interlayer coupling via the chalcogen atoms at apical sites, which reduces the bandgap and enhances the cleavage energy. In contrast, the varnishing interlayer hopping in the two-dimensional limit results in the formation of ultra-FB in the monolayers of these compounds. The easy exfoliation and the existence of unique ultra-FB near $E_{\rm F}$ make Pd$_{3}$P$_{2}$(S$_{1-x}$Se$_{x}$)$_{8}$ a model system to explore the exotic physics of FB in 2D kagome lattice., Comment: 6 pages, 4 figures

Published

2021

5. LaO as a candidate substrate for realizing superconductivity in FeSe epitaxial film

Author

Qiu, Xiao-Le, Gong, Ben-Chao, Yang, Huan-Cheng, Lu, Zhong-Yi, and Liu, Kai

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

The significantly enhanced superconducting transition temperature ($T_c$) of an FeSe monolayer on SrTiO$_3$(001) substrate has attracted extensive attention in recent years. Here, based on first-principles electronic structure calculations, we propose another candidate substrate LaO(001) for the epitaxial growth of FeSe monolayer to realize superconductivity. Our calculations show that for the optimal adsorption structure of FeSe monolayer on LaO(001), the stripe antiferromagnetic state and the dimer antiferromagnetic state are almost energetically degenerate, indicating the existence of strong magnetic fluctuation that is beneficial to the appearance of superconductivity. According to the Bader charge analysis, the calculated electron doping from the LaO substrate to the FeSe monolayer is about 0.18 electrons per Fe atom, even larger than that in case of FeSe/SrTiO$_3$(001). Since LaO was also reported to be a superconductor with $T_c$ ~ 5 K, it may have a superconducting proximity effect on the epitaxial FeSe film and vice versa. These results suggest that LaO would be an interesting substrate to study the interface-related superconductivity., Comment: 7 pages, 6 figures, 1 table

Published

2021

6. Theoretical design of all-carbon networks with intrinsic magnetism

Author

Gao, Yan, Feng, Xiaolong, Gong, Ben-Chao, Zhong, Chengyong, Yang, Shengyuan A., Liu, Kai, and Lu, Zhong-Yi

Subjects

Condensed Matter - Materials Science

Abstract

To induce intrinsic magnetism in the nominally nonmagnetic carbon materials containing only $s$ and $p$ electrons is an intriguing yet challenging task. Here, based on first-principles electronic structure calculations, we propose a universal approach inspired by Ovchinnikov's rule to guide us the design of a series of imaginative magnetic all-carbon structures. The idea is to combine the differently stacked graphene layers via the acetylenic linkages (-C$\equiv$C-) to obtain a class of two-dimensional (2D) and three-dimensional (3D) carbon networks. With first-principles electronic structure calculations, we confirm the effectiveness of this approach via concrete examples of double-layer ALBG-C14, triple-layer ALTG-C22, and bulk IALG-C30. We show that these materials are antiferromagnetic (AFM) semiconductors with intralayer N\'eel and interlayer AFM couplings. According to the above idea, our work not only provides a promising design scheme for magnetic all-carbon materials, but also can apply to other $\pi$-bonding network systems., Comment: 19 pages, 5 pages, 3 tables

Published

2021

7. Ionic liquid gating induced two superconductor-insulator phase transitions in spinel oxide Li$_{1 \pm x}$Ti$_2$O$_{4-\delta}$

Author

Wei, Zhongxu, Li, Qian, Gong, Ben-Chao, Wei, Xinjian, Hu, Wei, Ni, Zhuang, He, Ge, Qin, Mingyang, Kusmartseva, Anna, Kusmartsev, Fedor V., Yuan, Jie, Zhu, Beiyi, Chen, Qihong, Chen, Jian-Hao, Liu, Kai, and Jin, Kui

Subjects

Condensed Matter - Superconductivity

Abstract

The associations between emergent physical phenomena (e.g., superconductivity) and orbital, charge, and spin degrees of freedom of $3d$ electrons are intriguing in transition metal compounds. Here, we successfully manipulate the superconductivity of spinel oxide Li$_{1\pm x}$Ti$_2$O$_{4-\delta}$ (LTO) by ionic liquid gating. A dome-shaped superconducting phase diagram is established, where two insulating phases are disclosed both in heavily electron-doping and hole-doping regions. The superconductor-insulator transition (SIT) in the hole-doping region can be attributed to the loss of Ti valence electrons. In the electron-doping region, LTO exhibits an unexpected SIT instead of a metallic behavior despite an increase in carrier density. Furthermore, a thermal hysteresis is observed in the normal state resistance curve, suggesting a first-order phase transition. We speculate that the SIT and the thermal hysteresis stem from the enhanced $3d$ electron correlations and the formation of orbital ordering by comparing the transport and structural results of LTO with the other spinel oxide superconductor MgTi$_2$O$_4$, as well as analysing the electronic structure by first-principles calculations. Further comprehension of the detailed interplay between superconductivity and orbital ordering would contribute to the revealing of unconventional superconducting pairing mechanism., Comment: 6 pages, 4 figures

Published

2021

8. Emergent superconductivity in single crystalline $\mathrm{MgTi}_2\mathrm{O}_4$ films via structural engineering

Author

Hu, Wei, Feng, Zhongpei, Gong, Ben-Chao, He, Ge, Li, Dong, Qin, Mingyang, Shi, Yujun, Li, Qian, Zhang, Qinghua, Yuan, Jie, Zhu, Beiyi, Liu, Kai, Xiang, Tao, Gu, Lin, Zhou, Fang, Dong, Xiaoli, Zhao, Zhongxian, and Jin, Kui

Subjects

Condensed Matter - Superconductivity

Abstract

Spinel compounds have demonstrated rich functionalities but rarely shown superconductivity. Here, we report the emergence of superconductivity in the spinel $\mathrm{MgTi}_2\mathrm{O}_4$, known to be an insulator with a complicated order. The superconducting transition is achieved by engineering a superlattice of $\mathrm{MgTi}_2\mathrm{O}_4$ and $\mathrm{SrTiO}_3$. The onset transition temperature in the $\mathrm{MgTi}_2\mathrm{O}_4$ layer can be tuned from 0 to 5 K in such geometry, concurrently with a stretched $c$-axis (from 8.51 to 8.53 \AA) compared to the bulk material. Such a positive correlation without saturation suggests ample room for the further enhancement. Intriguingly, the superlattice exhibits isotropic upper critical field $H_{\mathrm{c}2}$ that breaks the Pauli limit, distinct from the highly anisotropic feature of interface superconductivity. The origin of superconductivity in the $\mathrm{MgTi}_2\mathrm{O}_4$ layer is understood in combination with the electron energy loss spectra and the first-principles electronic structure calculations, which point to the birth of superconductivity in the $\mathrm{MgTi}_2\mathrm{O}_4$ layer by preventing the Ti-Ti dimerization. Our discovery not only provides a platform to explore the interplay between the superconductivity and other exotic states, but also opens a new window to realize superconductivity in the spinel compounds as well as other titanium oxides., Comment: 5 pages, 4 figures

Published

2019

9. The melilite-type compound (Sr$_{1-x}$,$A_x$)$_2$MnGe$_2$S$_6$O ($A$=K, La) being a room temperature ferromagnetic semiconductor

Author

Yang, Huan-Cheng, Gong, Ben-Chao, Liu, Kai, and Lu, Zhong-Yi

Subjects

Condensed Matter - Materials Science

Abstract

The seeking of room temperature ferromagnetic semiconductors, which take advantages of both the charge and spin degrees of freedom of electrons to realize a variety of functionalities in devices integrated with electronic, optical, and magnetic storage properties, has been a long-term goal of scientists and engineers. Here, by using the spin-polarized density functional theory calculations, we predict a new series of high temperature ferromagnetic semiconductors based on the melilite-type oxysulfide Sr$_2$MnGe$_2$S$_6$O through hole (K) and electron (La) doping. Due to the lack of strong antiferromagnetic superexchange between Mn ions, the weak antiferromagnetic order in the parent compound Sr$_2$MnGe$_2$S$_6$O can be suppressed easily by charge doping with either $p$-type or $n$-type carriers, giving rise to the expected ferromagnetic order. At a doping concentration of 25%, both the hole-doped and electron-doped compounds can achieve a Curie temperature ($T_\text{c}$) above 300 K. The underlying mechanism is analyzed. Our study provides an effective approach for exploring new types of high temperature ferromagnetic semiconductors., Comment: 6 pages, 4 figures, 1 table

Published

2018

10. Exploring charge and spin fluctuations in infinite-layer cuprate SrCuO2 from a phonon perspective.

Author

Du, Xin, Sun, Pei-Han, Gong, Ben-Chao, Zhang, Jian-Feng, Lu, Zhong-Yi, and Liu, Kai

Abstract

The infinite-layer cuprate ACuO2 (A = Ca, Sr, Ba) possesses the simplest crystal structure among numerous cuprate superconductors and can serve as a prototypical system to explore the unconventional superconductivity. Based on the first-principles electronic structure calculations, we have studied the electronic and magnetic properties of the infinite-layer cuprate SrCuO2 from a phonon perspective. We find that interesting fluctuations of charges, electrical dipoles, and local magnetic moments can be induced by the atomic displacements of phonon modes in SrCuO2 upon the hole doping. Among all optical phonon modes of SrCuO2 in the antiferromagnetic Néel state, only the A1g mode that involves the full-breathing O vibrations along the Cu-O bonds can cause significant fluctuations of local magnetic moments on O atoms and dramatic charge redistributions between Cu and O atoms. Notably, due to the atomic displacements of the A1g mode, both the charge fluctuations on Cu and the electrical dipoles on O show a dome-like evolution with increasing hole doping, quite similar to the experimentally observed behavior of the superconducting Tc; in comparison, the fluctuations of local magnetic moments on O display a monotonic enhancement along with the hole doping. Further analyses indicate that around the optimal doping, there exists a large softening in the frequency of the A1g phonon mode and a van Hove singularity in the electronic structure close to the Fermi level, suggesting potential electron-phonon coupling. Our work reveals the important role of the full-breathing O phonon mode playing in the infinite-layer SrCuO2, which may provide new insights in understanding the cuprate superconductivity. [ABSTRACT FROM AUTHOR]

Published

2024

11. Magnetic proximity effect in LaO/EuO heterostructures: A first-principles study

Author

Sun, Pei-Han, primary, Man, Xiao-Xiao, additional, Gong, Ben-Chao, additional, Lu, Zhong-Yi, additional, and Liu, Kai, additional

Published

2023

12. Spin‐resolved imaging of antiferromagnetic order in Fe 4 Se 5 ultrathin films on SrTiO 3

Author

Zhang, Wenhao, primary, Zhang, Zhi‐Mo, additional, Nie, Jin‐Hua, additional, Gong, Ben‐Chao, additional, Cai, Min, additional, Liu, Kai, additional, Lu, Zhong‐Yi, additional, and Fu, Ying‐Shuang, additional

Published

2023

13. Self-Intercalated 1T-FeSe2 as an Effective Kagome Lattice

Author

Zhang, Zhi-Mo, primary, Gong, Ben-Chao, additional, Nie, Jin-Hua, additional, Meng, Fanqi, additional, Zhang, Qinghua, additional, Gu, Lin, additional, Liu, Kai, additional, Lu, Zhong-Yi, additional, Fu, Ying-Shuang, additional, and Zhang, Wenhao, additional

Published

2023

14. Intrinsic ferromagnetic axion states and single pair of Weyl fermions in the stable-state MnX2B2T6 family of materials

Author

Gao, Yan, primary, Wu, Weikang, additional, Gong, Ben-Chao, additional, Yang, Huan-Cheng, additional, Zhou, Xiang-Feng, additional, Liu, Yong, additional, Yang, Shengyuan A., additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2023

15. Magnetization-induced phase transition from a semimetal to a Chern insulator in monolayer VGa2Te4

Author

Gong, Ben-Chao, primary, Gao, Yan, additional, Qiu, Xiao-Le, additional, Zhao, Ning-Ning, additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2022

16. First-principles study on the magnetic and electronic properties of the high-pressure orthorhombic phase of MnSe

Author

Man, Xiao-Xiao, primary, Gong, Ben-Chao, additional, Sun, Pei-Han, additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2022

17. Spin‐Resolved Imaging of Antiferromagnetic Order in Fe4Se5 Ultrathin Films on SrTiO3.

Author

Zhang, Wenhao, Zhang, Zhi‐Mo, Nie, Jin‐Hua, Gong, Ben‐Chao, Cai, Min, Liu, Kai, Lu, Zhong‐Yi, and Fu, Ying‐Shuang

Published

2023

18. Spin‐Resolved Imaging of Antiferromagnetic Order in Fe4Se5 Ultrathin Films on SrTiO3.

Author

Zhang, Wenhao, Zhang, Zhi‐Mo, Nie, Jin‐Hua, Gong, Ben‐Chao, Cai, Min, Liu, Kai, Lu, Zhong‐Yi, and Fu, Ying‐Shuang

Published

2023

19. Superconductivity emerging from a pressurized van der Waals kagome material Pd3P2S8.

Author

Wang, Qi, Qiu, Xiao-Le, Pei, Cuiying, Gong, Ben-Chao, Gao, Lingling, Zhao, Yi, Cao, Weizheng, Li, Changhua, Zhu, Shihao, Zhang, Mingxin, Chen, Yulin, Liu, Kai, and Qi, Yanpeng

Subjects

SUPERCONDUCTING transition temperature, VAN der Waals forces, SUPERCONDUCTIVITY, QUANTUM states, RAMAN spectroscopy

Abstract

Kagome materials have been reported to possess abundant and peculiar physical properties, which provide an excellent platform to explore exotic quantum states. We present a discovery of superconductivity in van der Waals material Pd3P2S8 composed of Pd kagome lattice under pressure. Pd3P2S8 displays superconductivity for those pressures where the semiconducting-like temperature dependence of the resistivity turns into a metallic one. Moreover, it is found that the increased pressure results in a gradual enhancement of superconducting transition temperature, which finally reaches 6.83 K at 79.5 GPa. Combining high-pressure x-ray diffraction, Raman spectroscopy and theoretical calculations, our results demonstrate that the observed superconductivity induced by high pressure in Pd3P2S8 is closely related to the formation of amorphous phase, which results from the structural instability due to the enhanced coupling between interlayer Pd and S atoms upon compression. [ABSTRACT FROM AUTHOR]

Published

2023

20. Evolution of ultraflat band in the van der Waals kagome semiconductor Pd3P2(S1−xSex)8

Author

Yan, Shaohua, primary, Gong, Ben-Chao, additional, Wang, Lin, additional, Wu, Jinzhi, additional, Yin, Qiangwei, additional, Cao, Xinyu, additional, Zhang, Xiao, additional, Liu, Xiaofeng, additional, Lu, Zhong-Yi, additional, Liu, Kai, additional, and Lei, Hechang, additional

Published

2022

21. Self-Intercalated 1T-FeSe2 as an Effective Kagome Lattice.

Author

Zhang, Zhi-Mo, Gong, Ben-Chao, Nie, Jin-Hua, Meng, Fanqi, Zhang, Qinghua, Gu, Lin, Liu, Kai, Lu, Zhong-Yi, Fu, Ying-Shuang, and Zhang, Wenhao

Published

2023

22. Modulating charge density wave states in TaSe2 by an electride substrate

Author

Qiu, Xiao-Le, primary, Zhang, Jian-Feng, additional, Gong, Ben-Chao, additional, Yang, Huan-Cheng, additional, Lu, Zhong-Yi, additional, and Liu, Kai, additional

Published

2021

23. Inducing high- Tc ferromagnetism in the van der Waals crystal Mn(ReO4)2 via charge doping: A first-principles study

Author

Gong, Ben-Chao, primary, Yang, Huan-Cheng, additional, Zhang, Jian-Feng, additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2021

24. Theoretical design of all-carbon networks with intrinsic magnetism

Author

Gao, Yan, primary, Feng, Xiaolong, additional, Gong, Ben-Chao, additional, Zhong, Chengyong, additional, Yang, Shengyuan A., additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2021

25. Ionic liquid gating induced two superconductor-insulator phase transitions in spinel oxide Li$_{1 \pm x}$Ti$_2$O$_{4-��}$

Author

Wei, Zhongxu, Li, Qian, Gong, Ben-Chao, Wei, Xinjian, Hu, Wei, Ni, Zhuang, He, Ge, Qin, Mingyang, Kusmartseva, Anna, Kusmartsev, Fedor V., Yuan, Jie, Zhu, Beiyi, Chen, Qihong, Chen, Jian-Hao, Liu, Kai, and Jin, Kui

Subjects

Superconductivity (cond-mat.supr-con), Condensed Matter::Materials Science, Condensed Matter::Superconductivity, FOS: Physical sciences, Condensed Matter::Strongly Correlated Electrons

Abstract

The associations between emergent physical phenomena (e.g., superconductivity) and orbital, charge, and spin degrees of freedom of $3d$ electrons are intriguing in transition metal compounds. Here, we successfully manipulate the superconductivity of spinel oxide Li$_{1\pm x}$Ti$_2$O$_{4-��}$ (LTO) by ionic liquid gating. A dome-shaped superconducting phase diagram is established, where two insulating phases are disclosed both in heavily electron-doping and hole-doping regions. The superconductor-insulator transition (SIT) in the hole-doping region can be attributed to the loss of Ti valence electrons. In the electron-doping region, LTO exhibits an unexpected SIT instead of a metallic behavior despite an increase in carrier density. Furthermore, a thermal hysteresis is observed in the normal state resistance curve, suggesting a first-order phase transition. We speculate that the SIT and the thermal hysteresis stem from the enhanced $3d$ electron correlations and the formation of orbital ordering by comparing the transport and structural results of LTO with the other spinel oxide superconductor MgTi$_2$O$_4$, as well as analysing the electronic structure by first-principles calculations. Further comprehension of the detailed interplay between superconductivity and orbital ordering would contribute to the revealing of unconventional superconducting pairing mechanism., 6 pages, 4 figures

Published

2021

26. Two superconductor-insulator phase transitions in the spinel oxide Li1±xTi2O4−δ induced by ionic liquid gating

Author

Wei, Zhongxu, primary, Li, Qian, additional, Gong, Ben-Chao, additional, Wei, Xinjian, additional, Hu, Wei, additional, Ni, Zhuang, additional, He, Ge, additional, Qin, Mingyang, additional, Kusmartseva, Anna, additional, Kusmartsev, Fedor V., additional, Yuan, Jie, additional, Zhu, Beiyi, additional, Chen, Qihong, additional, Chen, Jian-Hao, additional, Liu, Kai, additional, and Jin, Kui, additional

Published

2021

27. LaO as a candidate substrate for realizing superconductivity in an FeSe epitaxial film

Author

Qiu, Xiao-Le, primary, Gong, Ben-Chao, additional, Yang, Huan-Cheng, additional, Lu, Zhong-Yi, additional, and Liu, Kai, additional

Published

2021

28. Emergent superconductivity in single-crystalline MgTi2O4 films via structural engineering

Author

Hu, Wei, primary, Feng, Zhongpei, additional, Gong, Ben-Chao, additional, He, Ge, additional, Li, Dong, additional, Qin, Mingyang, additional, Shi, Yujun, additional, Li, Qian, additional, Zhang, Qinghua, additional, Yuan, Jie, additional, Zhu, Beiyi, additional, Liu, Kai, additional, Xiang, Tao, additional, Gu, Lin, additional, Zhou, Fang, additional, Dong, Xiaoli, additional, Zhao, Zhongxian, additional, and Jin, Kui, additional

Published

2020

29. Degenerate antiferromagnetic states in spinel oxide LiV2O4*

Author

Gong, Ben-Chao, primary, Yang, Huan-Cheng, additional, Jin, Kui, additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2020

30. Exploring charge and spin fluctuations in infinite-layer cuprate SrCuO2from a phonon perspective

Author

Du, Xin, Sun, Pei-Han, Gong, Ben-Chao, Zhang, Jian-Feng, Lu, Zhong-Yi, and Liu, Kai

Abstract

The infinite-layer cuprate ACuO2(A= Ca, Sr, Ba) possesses the simplest crystal structure among numerous cuprate superconductors and can serve as a prototypical system to explore the unconventional superconductivity. Based on the first-principles electronic structure calculations, we have studied the electronic and magnetic properties of the infinite-layer cuprate SrCuO2from a phonon perspective. We find that interesting fluctuations of charges, electrical dipoles, and local magnetic moments can be induced by the atomic displacements of phonon modes in SrCuO2upon the hole doping. Among all optical phonon modes of SrCuO2in the antiferromagnetic Néel state, only the A1gmode that involves the full-breathing O vibrations along the Cu-O bonds can cause significant fluctuations of local magnetic moments on O atoms and dramatic charge redistributions between Cu and O atoms. Notably, due to the atomic displacements of the A1gmode, both the charge fluctuations on Cu and the electrical dipoles on O show a dome-like evolution with increasing hole doping, quite similar to the experimentally observed behavior of the superconducting Tc; in comparison, the fluctuations of local magnetic moments on O display a monotonic enhancement along with the hole doping. Further analyses indicate that around the optimal doping, there exists a large softening in the frequency of the A1gphonon mode and a van Hove singularity in the electronic structure close to the Fermi level, suggesting potential electron-phonon coupling. Our work reveals the important role of the full-breathing O phonon mode playing in the infinite-layer SrCuO2, which may provide new insights in understanding the cuprate superconductivity.

Published

2024

31. Quasi-degenerate magnetic states in α-RuCl3

Author

Yang, Huan-Cheng, primary, Gong, Ben-Chao, additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2018

32. Degenerate antiferromagnetic states in spinel oxide LiV2O4.

Author

Gong, Ben-Chao, Yang, Huan-Cheng, Jin, Kui, Liu, Kai, and Lu, Zhong-Yi

Subjects

*MAGNETIC entropy, *MAGNETIC traps, *METAL-insulator transitions, *MAGNETIC properties, *DENSITY of states

Abstract

The magnetic and electronic properties of spinel oxide LiV2O4 have been systematically studied by using the spin-polarized first-principles electronic structure calculations. We find that a series of magnetic states, in which the ferromagnetic (FM) V4 tetrahedra are linked together through the corner-sharing antiferromagnetic (AFM) V4 tetrahedra, possess degenerate energies lower than those of other spin configurations. The large number of these energetically degenerated states being the magnetic ground state give rise to strong magnetic frustration as well as large magnetic entropy in LiV2O4. The corresponding band structure and density of states of such a typical magnetic state in this series, i.e., the ditetrahedron (DT) AFM state, demonstrate that LiV2O4 is in the vicinity of a metal–insulator transition. Further analysis suggests that the t2g and eg orbitals of the V atoms play different roles in the magnetic exchange interactions. Our calculations are consistent with previous experimental measurements and shed light on understanding the exotic magnetism and the heavy-fermion behavior of LiV2O4. [ABSTRACT FROM AUTHOR]

Published

2020

33. Degenerate antiferromagnetic states in spinel oxide LiV2O4.

Author

Gong, Ben-Chao, Yang, Huan-Cheng, Jin, Kui, Liu, Kai, and Lu, Zhong-Yi

Subjects

MAGNETIC entropy, MAGNETIC traps, METAL-insulator transitions, MAGNETIC properties, DENSITY of states

Abstract

The magnetic and electronic properties of spinel oxide LiV2O4 have been systematically studied by using the spin-polarized first-principles electronic structure calculations. We find that a series of magnetic states, in which the ferromagnetic (FM) V4 tetrahedra are linked together through the corner-sharing antiferromagnetic (AFM) V4 tetrahedra, possess degenerate energies lower than those of other spin configurations. The large number of these energetically degenerated states being the magnetic ground state give rise to strong magnetic frustration as well as large magnetic entropy in LiV2O4. The corresponding band structure and density of states of such a typical magnetic state in this series, i.e., the ditetrahedron (DT) AFM state, demonstrate that LiV2O4 is in the vicinity of a metal–insulator transition. Further analysis suggests that the t2g and eg orbitals of the V atoms play different roles in the magnetic exchange interactions. Our calculations are consistent with previous experimental measurements and shed light on understanding the exotic magnetism and the heavy-fermion behavior of LiV2O4. [ABSTRACT FROM AUTHOR]

Published

2020

34. The melilite-type compound(Sr1-x,Ax)2MnGe2S6O( A = K, La) being a room temperature ferromagnetic semiconductor

Author

Yang, Huan-Cheng, primary, Gong, Ben-Chao, additional, Liu, Kai, additional, and Lu, Zhong-Yi, additional

Published

2018

35. The melilite-type compound [formula omitted] (A = K, La) being a room temperature ferromagnetic semiconductor.

Author

Yang, Huan-Cheng, Gong, Ben-Chao, Liu, Kai, and Lu, Zhong-Yi

Published

2018

36. Self-Intercalated 1T-FeSe2as an Effective Kagome Lattice

Author

Zhang, Zhi-Mo, Gong, Ben-Chao, Nie, Jin-Hua, Meng, Fanqi, Zhang, Qinghua, Gu, Lin, Liu, Kai, Lu, Zhong-Yi, Fu, Ying-Shuang, and Zhang, Wenhao

Abstract

In kagome lattice, with the emergence of Dirac cones and flat band in electronic structure, it provides a versatile ground for exploring intriguing interplay among frustrated geometry, topology and correlation. However, such engaging interest is strongly limited by available kagome materials in nature. Here we report on a synthetic strategy of constructing kagome systems via self-intercalation of Fe atoms into the van der Waals gap of FeSe2via molecular beam epitaxy. Using low-temperature scanning tunneling microscopy, we unveil a kagome-like morphology upon intercalating a 2 × 2 ordered Fe atoms, resulting in a stoichiometry of Fe5Se8. Both the bias-dependent STM imaging and theoretical modeling calculations suggest that the kagome pattern mainly originates from slight but important reconstruction of topmost Se atoms, incurred by the nonequivalent subsurface Fe sites due to the intercalation. Our study demonstrates an alternative approach of constructing artificial kagome structures, which envisions to be tuned for exploring correlated quantum states.

Published

2023

37. Superconductivity emerging from a pressurized van der Waals kagome material Pd3P2S8.

Author

Wang, Qi, Qiu, Xiao-Le, Pei, Cuiying, Gong, Ben-Chao, Gao, Lingling, Zhao, Yi, Cao, Weizheng, Li, Changhua, Zhu, Shihao, Zhang, Mingxin, Chen, Yulin, Liu, Kai, and Qi, Yanpeng

Subjects

*SUPERCONDUCTING transition temperature, *VAN der Waals forces, *SUPERCONDUCTIVITY, *QUANTUM states, *RAMAN spectroscopy

Abstract

Kagome materials have been reported to possess abundant and peculiar physical properties, which provide an excellent platform to explore exotic quantum states. We present a discovery of superconductivity in van der Waals material Pd3P2S8 composed of Pd kagome lattice under pressure. Pd3P2S8 displays superconductivity for those pressures where the semiconducting-like temperature dependence of the resistivity turns into a metallic one. Moreover, it is found that the increased pressure results in a gradual enhancement of superconducting transition temperature, which finally reaches 6.83 K at 79.5 GPa. Combining high-pressure x-ray diffraction, Raman spectroscopy and theoretical calculations, our results demonstrate that the observed superconductivity induced by high pressure in Pd3P2S8 is closely related to the formation of amorphous phase, which results from the structural instability due to the enhanced coupling between interlayer Pd and S atoms upon compression. [ABSTRACT FROM AUTHOR]

Published

2023

38. Self-Intercalated 1T-FeSe 2 as an Effective Kagome Lattice.

Author

Zhang ZM, Gong BC, Nie JH, Meng F, Zhang Q, Gu L, Liu K, Lu ZY, Fu YS, and Zhang W

Abstract

In kagome lattice, with the emergence of Dirac cones and flat band in electronic structure, it provides a versatile ground for exploring intriguing interplay among frustrated geometry, topology and correlation. However, such engaging interest is strongly limited by available kagome materials in nature. Here we report on a synthetic strategy of constructing kagome systems via self-intercalation of Fe atoms into the van der Waals gap of FeSe 2 via molecular beam epitaxy. Using low-temperature scanning tunneling microscopy, we unveil a kagome-like morphology upon intercalating a 2 × 2 ordered Fe atoms, resulting in a stoichiometry of Fe 5 Se 8 . Both the bias-dependent STM imaging and theoretical modeling calculations suggest that the kagome pattern mainly originates from slight but important reconstruction of topmost Se atoms, incurred by the nonequivalent subsurface Fe sites due to the intercalation. Our study demonstrates an alternative approach of constructing artificial kagome structures, which envisions to be tuned for exploring correlated quantum states.

Published

2023

39. Quasi-degenerate magnetic states in α-RuCl 3 .

Author

Yang HC, Gong BC, Liu K, and Lu ZY

Abstract

Exploring quantum spin liquid (QSL) state has both fundamental scientific value and realistic application potential. Recently, α-RuCl 3 was experimentally observed to hold in-plane zigzag antiferromagnetic (AFM) order at low temperature, which was further proposed to be proximate to a Kitaev QSL ground state. We have studied the magnetic properties of α-RuCl 3 in the framework of electronic structure calculation based on density functional theory (DFT) with Hubbard U correction (DFT+U) and spin-orbit coupling. When the intra-orbital Hubbard interaction U and the inter-orbital Hund's coupling J adopt the commonly accepted values of U = 2.0 eV and J = 0.4 eV, the zigzag AFM order indeed owns the minimum energy, consistent with the experimental observation. More importantly, we find that compared with the ferromagnetic order in the previous theoretical studies, there exist a series of magnetic configurations energetically even closer to the zigzag AFM ground state. The further calculations and analysis indicate that these low-energy magnetic states are closely related to the electronic correlation effect of Ru 4d orbitals. By decreasing U and increasing J with just about 0.2 eV, they become energetically degenerate with the zigzag AFM order, inducing strong magnetic frustration and then yielding a state without long-range magnetic order but with nonzero local moments. Considering the facts that theoretically the pressure usually reduces the intra-orbital Hubbard interaction and meanwhile enhances the inter-orbital Hund's coupling, while experimentally the pressure drives α-RuCl 3 into a quantum disordered phase, our results provide a perspective to understand the exotic magnetic behaviors of α-RuCl 3 .

Published

2019