Your search keyword '"Wu, Kehui"' showing total 538 results

1. Evidence for Two-dimensional Weyl Fermions in Air-Stable Monolayer PtTe$_{1.75}$

Author

Cai, Zhihao, Cao, Haijun, Sheng, Haohao, Hu, Xuegao, Sun, Zhenyu, Zhao, Qiaoxiao, Gao, Jisong, Ideta, Shin-ichiro, Shimada, Kenya, Huang, Jiawei, Cheng, Peng, Chen, Lan, Yao, Yugui, Meng, Sheng, Wu, Kehui, Wang, Zhijun, and Feng, Baojie

Subjects

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

Abstract

The Weyl semimetals represent a distinct category of topological materials wherein the low-energy excitations appear as the long-sought Weyl fermions. Exotic transport and optical properties are expected because of the chiral anomaly and linear energy-momentum dispersion. While three-dimensional Weyl semimetals have been successfully realized, the quest for their two-dimensional (2D) counterparts is ongoing. Here, we report the realization of 2D Weyl fermions in monolayer PtTe$_{1.75}$, which has strong spin-orbit coupling and lacks inversion symmetry, by combined angle-resolved photoemission spectroscopy, scanning tunneling microscopy, second harmonic generation, X-ray photoelectron spectroscopy measurements, and first-principles calculations. The giant Rashba splitting and band inversion lead to the emergence of three pairs of critical Weyl cones. Moreover, monolayer PtTe$_{1.75}$ exhibits excellent chemical stability in ambient conditions, which is critical for future device applications. The discovery of 2D Weyl fermions in monolayer PtTe$_{1.75}$ opens up new possibilities for designing and fabricating novel spintronic devices., Comment: Nano Letters, In Press

Published

2024

2. One-dimensional flat bands in phosphorene nanoribbons with pentagonal nature

Author

Sun, Shuo, You, Jing-Yang, Cai, Zhihao, Su, Jie, Yang, Tong, Peng, Xinnan, Wang, Yihe, Geng, Daiyu, Gou, Jian, Huang, Yuli, Duan, Sisheng, Chen, Lan, Wu, Kehui, Wee, Andrew T. S., Feng, Yuan Ping, Zhang, Jia Lin, Lu, Jiong, Feng, Baojie, and Chen, Wei

Subjects

Condensed Matter - Materials Science

Abstract

Materials with topological flat bands can serve as a promising platform to investigate strongly interacting phenomena. However, experimental realization of ideal flat bands is mostly limited to artificial lattices or moir\'e systems. Here we report a general way to construct one-dimensional (1D) flat bands in phosphorene nanoribbons (PNRs) with pentagonal nature: penta-hexa-PNRs and penta-dodeca-PNRs, wherein the corresponding flat bands are directly verified by using angle-resolved photoemission spectroscopy. We confirm that the observed 1D flat bands originate from the electronic 1D sawtooth and Lieb lattices, respectively, as revealed by the combination of bond-resolved scanning tunneling microscopy, scanning tunneling spectroscopy, tight-binding models, and first-principles calculations. Our study demonstrates a general way to construct 1D flat bands in 1D solid materials system, which provides a robust platform to explore strongly interacting phases of matter., Comment: 13 pages, 4 figures

Published

2024

3. Evidence for Multiferroicity in Single-Layer CuCrSe$_2$

Author

Sun, Zhenyu, Su, Yueqi, Zhi, Aomiao, Gao, Zhicheng, Han, Xu, Wu, Kang, Bao, Lihong, Huang, Yuan, Shi, Youguo, Bai, Xuedong, Cheng, Peng, Chen, Lan, Wu, Kehui, Tian, Xuezeng, Wu, Changzheng, and Feng, Baojie

Subjects

Condensed Matter - Materials Science

Abstract

Multiferroic materials, which simultaneously exhibit ferroelectricity and magnetism, have attracted substantial attention due to their fascinating physical properties and potential technological applications. With the trends towards device miniaturization, there is an increasing demand for the persistence of multiferroicity in single-layer materials at elevated temperatures. Here, we report high-temperature multiferroicity in single-layer CuCrSe$_2$, which hosts room-temperature ferroelectricity and 120 K ferromagnetism. Notably, the ferromagnetic coupling in single-layer CuCrSe$_2$ is enhanced by the ferroelectricity-induced orbital shift of Cr atoms, which is distinct from both types I and II multiferroicity. These findings are supported by a combination of second-harmonic generation, piezo-response force microscopy, scanning transmission electron microscopy, magnetic, and Hall measurements. Our research provides not only an exemplary platform for delving into intrinsic magnetoelectric interactions at the single-layer limit but also sheds light on potential development of electronic and spintronic devices utilizing two-dimensional multiferroics.

Published

2024

4. Layer-dependent Raman spectroscopy of ultrathin Ta$_2$Pd$_3$Te$_5$

Author

Sun, Zhenyu, Guo, Zhaopeng, Yan, Dayu, Cheng, Peng, Chen, Lan, Shi, Youguo, Huang, Yuan, Wang, Zhijun, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science

Abstract

Two-dimensional topological insulators (2DTIs) or quantum spin Hall insulators are attracting increasing attention due to their potential applications in next-generation spintronic devices. Despite their promising prospects, realizable 2DTIs are still limited. Recently, Ta2Pd3Te5, a semiconducting van der Waals material, has shown spectroscopic evidence of quantum spin Hall states. However, achieving controlled preparation of few- to monolayer samples, a crucial step in realizing quantum spin Hall devices, has not yet been achieved. In this work, we fabricated few- to monolayer Ta$_2$Pd$_3$Te$_5$ and performed systematic thickness- and temperature-dependent Raman spectroscopy measurements. Our results demonstrate that Raman spectra can provide valuable information to determine the thickness of Ta2Pd3Te5 thin flakes. Moreover, our angle-resolved polarized Raman (ARPR) spectroscopy measurements show that the intensities of the Raman peaks are strongly anisotropic due to the quasi-one-dimensional atomic structure, providing a straightforward method to determine its crystalline orientation. Our findings may stimulate further efforts to realize quantum devices based on few or monolayer Ta$_2$Pd$_3$Te$_5$.

Published

2024

5. Unconventional band structure via combined molecular orbital and lattice symmetries in a surface-confined metallated graphdiyne sheet

Author

Piquero-Zulaica, Ignacio, Hu, Wenqi, Seitsonen, Ari Paavo, Haag, Felix, Küchle, Johannes, Allegretti, Francesco, Lyu, Yuanhao, Chen, Lan, Wu, Kehui, El-Fattah, Zakaria M. Abd, Aktürk, Ethem, Klyatskaya, Svetlana, Ruben, Mario, Muntwiler, Matthias, Barth, Johannes V., and Zhang, Yi-Qi

Subjects

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

Abstract

Graphyne (GY) and graphdiyne (GDY)-based materials represent an intriguing class of two-dimensional (2D) carbon-rich networks with tunable structures and properties surpassing those of graphene. However, the challenge of fabricating atomically well-defined crystalline GY/GDY-based systems largely hinders detailed electronic structure characterizations. Here, we report the emergence of an unconventional band structure in mesoscopically regular (~1 {\mu}m) metallated GDY sheets featuring a honeycomb lattice on Ag(111) substrates. Employing complementary scanning tunnelling and angle-resolved photoemission spectroscopies, electronic band formation with a gap of 2.5 eV is rigorously determined in agreement with real-space electronic characteristics. Extensive density functional theory calculations corroborate our observations as well as recent theoretical predictions that doubly degenerate frontier molecular orbitals on a honeycomb lattice give rise to flat, Dirac and Kagome bands close to Fermi level. These results illustrate the tremendous potential of engineering novel band structures via molecular orbital and lattice symmetries in atomically precise 2D carbon scaffolds.

Published

2023

6. Bound excitons and bandgap engineering in violet phosphorus

Author

Sun, Zhenyu, Cai, Zhihao, Cheng, Peng, Chen, Lan, Zhao, Xuewen, Zhang, Jinying, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science

Abstract

Violet phosphorus (VP), the most stable phosphorus allotrope, is a van der Waals semiconductor that can be used to construct $\textit{p}$-type nanodevices. Recently, high-quality VP crystals have been synthesized while a deep insight into their excitonic properties and bandgap tailoring approaches, which are crucial for their optoelectronic device applications, is still lacking. Here, we study the optical properties of ultrathin VP by second harmonic generation, photoluminescence, and optical absorption spectroscopy. We observed strong bound exciton emission that is 0.48 eV away from the free exciton emission, which is among the largest in 2D materials. In addition, the bandgaps of VP are highly sensitive to the number of layers and external strain, which provides convenient approaches for bandgap engineering. The strong bound exciton emission and tunable bandgaps make VP a promising material in optoelectronic devices.

Published

2023

7. Realization of a two-dimensional checkerboard lattice in monolayer Cu$_2$N

Author

Hu, Xuegao, Zhang, Run-Wu, Ma, Da-Shuai, Cai, Zhihao, Geng, Daiyu, Sun, Zhenyu, Zhao, Qiaoxiao, Gao, Jisong, Cheng, Peng, Chen, Lan, Wu, Kehui, Yao, Yugui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Two-dimensional checkerboard lattice, the simplest line-graph lattice, has been intensively studied as a toy model, while material design and synthesis remain elusive. Here, we report theoretical prediction and experimental realization of the checkerboard lattice in monolayer Cu$_2$N. Experimentally, monolayer Cu$_2$N can be realized in the well-known N/Cu(100) and N/Cu(111) systems that were previously mistakenly believed to be insulators. Combined angle-resolved photoemission spectroscopy measurements, first-principles calculations, and tight-binding analysis show that both systems host checkerboard-derived hole pockets near the Fermi level. In addition, monolayer Cu$_2$N has outstanding stability in air and organic solvents, which is crucial for further device applications., Comment: Nano Letters, in press

Published

2023

8. Observation of Gapped Dirac Cones in a Two-Dimensional Su-Schrieffer-Heeger Lattice

Author

Geng, Daiyu, Zhou, Hui, Yue, Shaosheng, Sun, Zhenyu, Cheng, Peng, Chen, Lan, Meng, Sheng, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

The Su-Schrieffer-Heeger (SSH) model in a two-dimensional rectangular lattice features gapless or gapped Dirac cones with topological edge states along specific peripheries. While such a simple model has been recently realized in photonic/acoustic lattices and electric circuits, its material realization in condensed matter systems is still lacking. Here, we study the atomic and electronic structure of a rectangular Si lattice on Ag(001) by angle-resolved photoemission spectroscopy and theoretical calculations. We demonstrate that the Si lattice hosts gapped Dirac cones at the Brillouin zone corners. Our tight-binding analysis reveals that the Dirac bands can be described by a 2D SSH model with anisotropic polarizations. The gap of the Dirac cone is driven by alternative hopping amplitudes in one direction and staggered potential energies in the other one and hosts topological edge states. Our results establish an ideal platform to explore the rich physical properties of the 2D SSH model., Comment: Accepted for publication in Nature Communications

Published

2022

9. Less Equal, Less Satisfied? Gender Inequality Hampers Adults’ Subjective Well-Being via Gender-Role Attitudes

Author

Chen, Lihua, Wu, Kehui, Du, Hongfei, King, Ronnel B., Chen, Anli, Li, Tongxiaoyu, and Chi, Peilian

Published

2023

10. Exfoliation of 2D van der Waals crystals in ultrahigh vacuum for interface engineering

Author

Sun, Zhenyu, Han, Xu, Cai, Zhihao, Yue, Shaosheng, Geng, Daiyu, Rong, Dongke, Zhao, Lin, Zhang, Yi-Qi, Cheng, Peng, Chen, Lan, Zhou, Xingjiang, Huang, Yuan, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science

Abstract

Two-dimensional (2D) materials and their heterostructures have been intensively studied in recent years due to their potential applications in electronic, optoelectronic, and spintronic devices. Nonetheless, the realization of 2D heterostructures with atomically flat and clean interfaces remains challenging, especially for air-sensitive materials, which hinders the in-depth investigation of interface-induced phenomena and the fabrication of high-quality devices. Here, we circumvented this challenge by exfoliating 2D materials in an ultrahigh vacuum. Remarkably, ultraflat and clean substrate surfaces can assist the exfoliation of 2D materials, regardless of the substrate and 2D material, thus providing a universal method for the preparation of heterostructures with ideal interfaces. In addition, we studied the properties of two prototypical systems that cannot be achieved previously, including the electronic structure of monolayer phospherene and optical responses of transition metal dichalcogenides on different metal substrates. Our work paves the way to engineer rich interface-induced phenomena, such as proximity effects and moir\'{e} superlattices., Comment: 17 pages, 4 figures

Published

2022

11. Atomic-scale Manipulation of Single-Polaron in a Two-Dimensional Semiconductor

Author

Liu, Huiru, Wang, Aolei, Zhang, Ping, Ma, Chen, Chen, Caiyun, Liu, Zijia, Zhang, Yiqi, Feng, Baojie, Cheng, Peng, Zhao, Jin, Chen, Lan, and Wu, Kehui

Subjects

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

Abstract

Polaron is a composite quasiparticle derived from an excess carrier trapped by local lattice distortion, and it has been studied extensively for decades both theoretically and experimentally. However, atomic-scale creation and manipulation of single-polarons in real space have still not been achieved so far, which precludes the atomistic understanding of the properties of polarons as well as their applications. Herein, using scanning tunneling microscopy, we succeeded to create single polarons in a monolayer two-dimensional semiconductor, CoCl2. Combined with first-principles calculations, two stable polaron configurations, centered at on-top and hollow sites, respectively, have been revealed. Remarkably, a series of manipulation progresses, from creation, erasure to transition, can be accurately implemented on individual polarons. Our results pave the way to understand the polaronic physics at atomic level, and the easy control of single polarons in 2D semiconductor may open the door to 2D polaronics including the data storage.

Published

2022

12. Impact of ankle-foot strengthening therapy on motor function in children with cerebral palsy

Author

Shi Jiaying, Peng Zijie, Shi Zhongyan, Wu Kehui, Huang Shaoxia, Ruan Jingyan

Subjects

cerebral palsy, child, ankle-foot strengthening therapy, trunk training, motor function, Medicine

Abstract

Objective To investigate the changes of motor function in children with cerebral palsy undergoing ankle-foot strengthening therapy. Methods A total of 80 children with cerebral palsy were enrolled in this study，and divided into the control group（n = 40）and observation group（n = 40）. In the control group，children received regular trunk training based on motor control theory combined with neurodevelopmental therapy，and those in the observation group received ankle-foot strengthening therapy in addition to those interventions in the control group. Pre-and post-treatment assessments including the Gross Motor Function Measure（GMFM-88）scores for Sections D and E，the 6-minute walk test（6-MWT），the Timed Up and Go Test（TUGT），and the Pediatric Balance Scale（PBS）were recorded to compare clinical efficacy between two groups. Results Following corresponding interventions，significant improvement was observed in all observed indexes in two groups（all P < 0.05）. Notably，children in the observation group exhibited better post-treatment scores in GMFM Section E，6-MWT，TUGT，and PBS compared to their counterparts in the control group，with statistically significant differences（all P < 0.05）. Conclusion Ankle-foot strengthening therapy effectively promotes the recovery of motor function in children with cerebral palsy.

Published

2024

13. Observation of topological flat bands in the kagome semiconductor Nb$_3$Cl$_8$

Author

Sun, Zhenyu, Zhou, Hui, Wang, Cuixiang, Kumar, Shiv, Geng, Daiyu, Yue, Shaosheng, Han, Xin, Haraguchi, Yuya, Shimada, Kenya, Cheng, Peng, Chen, Lan, Shi, Youguo, Wu, Kehui, Meng, Sheng, and Feng, Baojie

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

The destructive interference of wavefunctions in a kagome lattice can give rise to topological flat bands (TFBs) with a highly degenerate state of electrons. Recently, TFBs have been observed in several kagome metals, including Fe$_3$Sn$_2$, FeSn, CoSn, and YMn$_6$Sn$_6$. Nonetheless, kagome materials that are both exfoliable and semiconducting are lacking, which seriously hinders their device applications. Herein, we show that Nb$_3$Cl$_8$, which hosts a breathing kagome lattice, is gapped out because of the absence of inversion symmetry, while the TFBs survive because of the protection of the mirror reflection symmetry. By angle-resolved photoemission spectroscopy measurements and first-principles calculations, we directly observe the TFB and a moderate band gap in Nb$_3$Cl$_8$. By mechanical exfoliation, we successfully obtain monolayers of Nb$_3$Cl$_8$ and confirm that they are stable under ambient conditions. In addition, our calculations show that monolayers of Nb$_3$Cl$_8$ have a magnetic ground state, thus providing opportunities to study the interplay between geometry, topology, and magnetism., Comment: 6 pages, 4 figures

Published

2021

14. Observation of one-dimensional Dirac fermions in silicon nanoribbons

Author

Yue, Shaosheng, Zhou, Hui, Feng, Ya, Wang, Yue, Sun, Zhenyu, Geng, Daiyu, Arita, Masashi, Kumar, Shiv, Shimada, Kenya, Cheng, Peng, Chen, Lan, Yao, Yugui, Meng, Sheng, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Dirac materials, which feature Dirac cones in the reciprocal space, have been one of the hottest topics in condensed matter physics in the past decade. To date, 2D and 3D Dirac Fermions have been extensively studied, while their 1D counterparts are rare. Recently, Si nanoribbons (SiNRs), which are composed of alternating pentagonal Si rings, have attracted intensive attention. However, the electronic structure and topological properties of SiNRs are still elusive. Here, by angle-resolved photoemission spectroscopy, scanning tunneling microscopy/spectroscopy measurements, first-principles calculations, and tight-binding model analysis, we demonstrate the existence of 1D Dirac Fermions in SiNRs. Our theoretical analysis shows that the Dirac cones derive from the armchairlike Si chain in the center of the nanoribbon and can be described by the Su-Schrieffer-Heeger model. These results establish SiNRs as a platform for studying the novel physical properties in 1D Dirac materials., Comment: 4 figures

Published

2021

15. Lycopene alleviates Bisphenol a-induced lipid accumulation via activating the SIRT1/PGC-1α signaling in PK15 cells

Author

Song, Dan, Liu, Yuan, Wu, Kehui, Lyu, Manting, Wu, Yongshu, Zhang, Yanan, Wang, Panling, and Li, Xiangchen

Published

2024

16. Atomic-scale manipulation of single-polaron in a two-dimensional semiconductor

Author

Liu, Huiru, Wang, Aolei, Zhang, Ping, Ma, Chen, Chen, Caiyun, Liu, Zijia, Zhang, Yi-Qi, Feng, Baojie, Cheng, Peng, Zhao, Jin, Chen, Lan, and Wu, Kehui

Published

2023

17. Emergence of ferroelectricity in a nonferroelectric monolayer

Author

Li, Wenhui, Zhang, Xuanlin, Yang, Jia, Zhou, Song, Song, Chuangye, Cheng, Peng, Zhang, Yi-Qi, Feng, Baojie, Wang, Zhenxing, Lu, Yunhao, Wu, Kehui, and Chen, Lan

Published

2023

18. Condensation and asymmetric amplification of chirality in achiral molecules adsorbed on an achiral surface

Author

Liu, Huiru, Li, Heping, He, Yu, Cheng, Peng, Zhang, Yi-Qi, Feng, Baojie, Li, Hui, Wu, Kehui, and Chen, Lan

Published

2023

19. Observation of quantum spin Hall states in Ta$_2$Pd$_3$Te$_5$

Author

Wang, Xuguang, Geng, Daiyu, Yan, Dayu, Hu, Wenqi, Zhang, Hexu, Yue, Shaosheng, Sun, Zhenyu, Kumar, Shiv, Shimada, Kenya, Cheng, Peng, Chen, Lan, Nie, Simin, Wang, Zhijun, Shi, Youguo, Zhang, Yi-Qi, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science

Abstract

Two-dimensional topological insulators (2DTIs), which host the quantum spin Hall (QSH) effect, are one of the key materials in next-generation spintronic devices. To date, experimental evidence of the QSH effect has only been observed in a few materials, and thus, the search for new 2DTIs is at the forefront of physical and materials science. Here, we report experimental evidence of a 2DTI in the van der Waals material Ta$_2$Pd$_3$Te$_5$. First-principles calculations show that each monolayer of Ta$_2$Pd$_3$Te$_5$ is a 2DTI with weak interlayer interactions. Combined transport, angle-resolved photoemission spectroscopy, and scanning tunneling microscopy measurements confirm the existence of a band gap at the Fermi level and topological edge states inside the gap. These results demonstrate that Ta$_2$Pd$_3$Te$_5$ is a promising material for fabricating spintronic devices based on the QSH effect., Comment: 6 pages, 3 figures

Published

2020

20. Coercive Parenting and Juvenile Delinquency in China: Assessing Gender Differences in the Moderating Effect of Empathic Concern

Author

Wu, Kehui and Li, Spencer D.

Published

2023

21. Experimental observation of Dirac cones in artificial graphene lattices

Author

Yue, Shaosheng, Zhou, Hui, Geng, Daiyu, Sun, Zhenyu, Arita, Masashi, Shimada, Kenya, Cheng, Peng, Chen, Lan, Meng, Sheng, Wu, Kehui, and Feng, Baojie

Subjects

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

Abstract

Artificial lattices provide a tunable platform to realize exotic quantum devices. A well-known example is artificial graphene (AG), in which electrons are confined in honeycomb lattices and behave as massless Dirac fermions. Recently, AG systems have been constructed by manipulating molecules using scanning tunnelling microscope tips, but the nanoscale size typical for these constructed systems are impossible for practical device applications and insufficient for direct investigation of the electronic structures using angle-resolved photoemission spectroscopy (ARPES). Here, we demonstrate the synthesis of macroscopic AG by self-assembly of C$_{60}$ molecules on metal surfaces. Our theoretical calculations and ARPES measurements directly confirm the existence of Dirac cones at the $K$ ($K^\prime$) points of the Brillouin zone (BZ), in analogy to natural graphene. These results will stimulate ongoing efforts to explore the exotic properties in artificial lattices and provide an important step forward in the realization of novel molecular quantum devices., Comment: to appear in Physical Review B

Published

2020

22. Superconductivity and Fermi Surface Nesting in the Candidate Dirac Semimetal NbC

Author

Yan, Dayu, Geng, Daiyu, Gao, Qiang, Cui, Zhihai, Yi, Changjiang, Feng, Ya, Song, Chunyao, Luo, Hailan, Yang, Meng, Arita, Masashi, Kumar, Shiv, Schwier, Eike F., Shimada, Kenya, Zhao, Lin, Wu, Kehui, Weng, Hongmini, Chen, Lan, Zhou, X. J., Wang, Zhijun, Shi, Youguo, and Feng, Baojie

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

We report the synthesis of single-crystal NbC, a transition metal carbide with various unusual properties. Transport, magnetic susceptibility, and specific heat measurements demonstrate that NbC is a conventional superconductor with a superconducting transition temperature ($T_c$) of 11.5 K. Our theoretical calculations show that NbC is a type-II Dirac semimetal with strong Fermi surface nesting, which is supported by our ARPES measurement results. We also observed the superconducting gaps of NbC using angle-resolved photoemission spectroscopy (ARPES) and found some unconventional behaviors. These intriguing superconducting and topological properties, combined with the high corrosion resistance, make NbC an ideal platform for both fundamental research and device applications., Comment: to appear in Physical Review B

Published

2020

23. Topological electronic structure in the antiferromagnet HoSbTe

Author

Yue, Shaosheng, Qian, Yuting, Yang, Meng, Geng, Daiyu, Yi, Changjiang, Kumar, Shiv, Shimada, Kenya, Cheng, Peng, Chen, Lan, Wang, Zhijun, Weng, Hongming, Shi, Youguo, Wu, Kehui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Magnetic topological materials, in which the time-reversal symmetry is broken, host various exotic quantum phenomena, including the quantum anomalous Hall effect, axion insulator states, and Majorana fermions. The study of magnetic topological materials is at the forefront of condensed matter physics. Recently, a variety of magnetic topological materials have been reported, such as Mn$_3$Sn, Co$_3$Sn$_2$S$_2$, Fe$_3$Sn$_2$, and MnBi$_2$Te$_4$. Here, we report the observation of a topological electronic structure in an antiferromagnet, HoSbTe, a member of the ZrSiS family of materials, by angle-resolved photoemission spectroscopy measurements and first-principles calculations. We demonstrate that HoSbTe is a Dirac nodal line semimetal when spin-orbit coupling (SOC) is neglected. However, our theoretical calculations show that the strong SOC in HoSbTe fully gaps out the nodal lines and drives the system to a weak topological insulator state, with each layer being a two-dimensional topological insulator. Because of the strong SOC in HoSbTe, the gap is as large as hundreds of meV along specific directions, which is directly observed by our ARPES measurements. The existence of magnetic order and topological properties in HoSbTe makes it a promising material for realization of exotic quantum devices., Comment: 5 pages, 3 figures

Published

2020

24. Experimental evidence of monolayer AlB$_2$ with symmetry-protected Dirac cones

Author

Geng, Daiyu, Yu, Kejun, Yue, Shaosheng, Cao, Jin, Li, Wenbin, Ma, Dashuai, Cui, Chaoxi, Arita, Masashi, Kumar, Shiv, Schwier, Eike F., Shimada, Kenya, Cheng, Peng, Chen, Lan, Wu, Kehui, Yao, Yugui, and Feng, Baojie

Subjects

Condensed Matter - Materials Science

Abstract

Monolayer AlB$_2$ is composed of two atomic layers: honeycomb borophene and triangular aluminum. In contrast with the bulk phase, monolayer AlB$_2$ is predicted to be a superconductor with a high critical temperature. Here, we demonstrate that monolayer AlB$_2$ can be synthesized on Al(111) via molecular beam epitaxy. Our theoretical calculations revealed that the monolayer AlB$_2$ hosts several Dirac cones along the $\Gamma$--M and $\Gamma$--K directions; these Dirac cones are protected by crystal symmetries and are thus resistant to external perturbations. The extraordinary electronic structure of the monolayer AlB$_2$ was confirmed via angle-resolved photoemission spectroscopy measurements. These results are likely to stimulate further research interest to explore the exotic properties arising from the interplay of Dirac fermions and superconductivity in two-dimensional materials., Comment: 5 pages, 4 figures

Published

2020

25. Robust Gapless Surface State against Surface Magnetic Impurities on (Bi$_{0.5}$Sb$_{0.5}$)$_2$Te$_3$ Evidenced by In Situ Magnetotransport Measurements

Author

Yu, Liuqi, Hu, Longqian, Barreda, Jorge L., Guan, Tong, He, Xiaoyue, Wu, Kehui, Li, Yongqing, and Xiong, Peng

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Despite extensive experimental and theoretical efforts, the important issue of the effects of surface magnetic impurities on the topological surface state of a topological insulator (TI) remains unresolved. We elucidate the effects of Cr impurities on epitaxial thin films of (Bi$_{0.5}$Sb$_{0.5}$)$_{2}$Te$_{3}$: Cr adatoms are incrementally deposited onto the TI held in ultrahigh vacuum at low temperatures, and \textit{in situ} magnetoconductivity and Hall effect measurements are performed at each increment with electrostatic gating. In the experimentally identified surface transport regime, the measured minimum electron density shows a non-monotonic evolution with the Cr density ($n_{\mathrm{Cr}}$): it first increases and then decreases with $n_{\mathrm{Cr}}$. This unusual behavior is ascribed to the dual roles of the Cr as ionized impurities and electron donors, having competing effects of enhancing and decreasing the electronic inhomogeneities in the surface state at low and high $n_{\mathrm{Cr}}$ respectively. The magnetoconductivity is obtained for different $n_{\mathrm{Cr}}$ on one and the same sample, which yields clear evidence that the weak antilocalization effect persists and the surface state remains gapless up to the highest $n_{\mathrm{Cr}}$, contrary to the expectation that the deposited Cr should break the time reversal symmetry and induce a gap opening at the Dirac point.

Published

2020

26. The Relationship Between Perineural Invasion and Extranodal Extension in Papillary Thyroid Cancer

Author

Luo, Xiaochuan, Wu, Kehui, Geng, Xiaochen, Yang, Tian, and Meng, Xianying

Published

2023

27. One Dimensional Nearly Free Electron States in Borophene

Author

Kong, Longjuan, Liu, Liren, Chen, Lan, Zhong, Qing, Cheng, Peng, Li, Hui, Zhang, Zhuhua, and Wu, Kehui

Subjects

Condensed Matter - Materials Science

Abstract

Two-dimensional boron (borophene) is featured by its structural polymorphs and distinct in-plane anisotropy, opening opportunities to achieve tailored electronic properties by intermixing different phases. Here, using scanning tunneling spectroscopy combined with first-principles calculations, delocalized one-dimensional nearly free electron states (NFE) in the (2,3) or \b{eta}12 borophene sheet on the Ag(111) surface were observed. The NFE states emerge from a line defect in the borophene, manifested as a structural unit of the (2,2) or \c{hi}3 sheet, which creates an in-plane potential well that shifts the states toward the Fermi level. The NFE states are held in the 2D plane of borophene, rather than in the vacuum region as observed in other nanostructures. Furthermore the borophene can provide a rare prototype to further study novel NFE behaviors, which may have potential applications on transport or field emission nanodevices based on boron., Comment: 4 figures

Published

2019

28. Epitaxial growth of borophene on substrates

Author

Li, Wenhui, Wu, Kehui, and Chen, Lan

Published

2023

29. Electronic Structures of Borophene

Author

Feng, Baojie, Sugino, Osamu, Wu, Kehui, Matsuda, Iwao, editor, and Wu, Kehui, editor

Published

2021

30. Synthesis of Borophene

Author

Feng, Baojie, Chen, Lan, Wu, Kehui, Matsuda, Iwao, editor, and Wu, Kehui, editor

Published

2021

31. Switchable quantized conductance in topological insulators revealed by the Shockley-Ramo theorem

Author

Seifert, Paul, Kundinger, Marinus, Shi, Gang, He, Xiaoyue, Wu, Kehui, Li, Yongqing, Holleitner, Alexander, and Kastl, Christoph

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Crystals with symmetry-protected topological order, such as topological insulators, promise coherent spin and charge transport phenomena even in the presence of disorder at room temperature. Still, a major obstacle towards an application of topological surface states in integrated circuits is a clear, reliable, and straightforward read-out independent of a prevailing charge carrier density in the bulk. Here, we demonstrate how to image and read-out the local conductance of helical surface modes in the prototypical topological insulators Bi2Se3 and BiSbTe3. We apply the so-called Shockley-Ramo theorem to design an optoelectronic probe circuit for the gapless surface states, and surprisingly find a precise conductance quantization at 1e2/h. The unprecedented response is a clear signature of local spin-polarized transport, and it can be switched on and off via an electrostatic field effect. The macroscopic, global read-out scheme is based on the displacement current resistivity, and it does not require coherent transport between electrodes.6 It provides a generalizable platform for studying further non-trivial gapless systems such as Weyl-semimetals and quantum spin-Hall insulators.

Published

2018

32. Experimental realization of graphene-like borophene

Author

Li, Wenbin, Kong, Longjuan, Chen, Caiyun, Gou, Jian, Sheng, Shaoxiang, Zhang, Weifeng, Li, Hui, Chen, Lan, Cheng, Peng, and Wu, Kehui

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report a successful preparation of a purely honeycomb, graphene-like borophene, by using an Al(111) surface as the substrate and molecular beam epitaxy (MBE) growth in ultrahigh vacuum. Our scanning tunneling microscopy (STM) reveals perfect monolayer borophene with planar, non-buckled honeycomb lattice similar as graphene. Theoretical calculations show that the honeycomb borophene on Al(111) is energetically stable. Remarkably, nearly one electron charge is transferred to each boron atom from the Al(111) substrate and stabilizes the honeycomb borophene structure, in contrast to the little charge transfer in borophene/Ag(111) case. This work demonstrates that the borophene lattice can be manipulated by controlling the charge transfer between the substrate and the borophene film., Comment: 3 figures, 1 table

Published

2017

33. Gender Inequality Lowers Educational Aspiration for Adolescent Boys and Girls: A Multi-Level and Longitudinal Study in China

Author

Chen, Lihua, Li, Tongxiaoyu, King, Ronnel B., Du, Hongfei, Wu, Kehui, and Chi, Peilian

Published

2022

34. Direct evidences of pentagonal silicon chains and magic clusters

Author

Sheng, Shaoxiang, Ma, Runze, Wu, Jiangbin, Li, Wenbin, Kong, Longjuan, Cong, Xin, Cao, Duanyun, Hu, Wenqi, Luo, Jun-Wei, Cheng, Peng, Tan, Ping-Heng, Jiang, Ying, Chen, Lan, and Wu, Kehui

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Pentagon is one of the most beautiful geometric structures in nature, but it is rarely seen simply because five-fold symmetry is mathematically forbidden in a 2D or 3D periodic lattices. Fortunately, pentagon as a structural element is allowed in 1D or 0D systems, since translational symmetry is not necessary there. However, in these systems pentagons only compose a small portion of the structure. So far, 1D or 0D systems consisting of purely pentagons are still rare. Here, combing high resolution non-contact atomic force microscopy and tip-enhanced Raman spectroscopy, we have directly visualized the pentagon-ring structure in self-assembled Si nanoribbons and magic clusters on Ag(110) substrate. Moreover, chemical fingerprint of Si pentagon was detected in individual Si nanoribbon and clusters by tip-enhanced Raman spectroscopy. This work demonstrates that Si pentagon can be an important element in building silicon nanostructures, which may find potential applications in future nanoelectronics based on silicon., Comment: 4 figures

Published

2017

35. Realization of Flat Band with Possible Nontrivial Topology in Electronic Kagome Lattice

Author

Li, Zhi, Zhuang, Jincheng, Chen, Lan, Wang, Li, Feng, Haifeng, Xu, Xun, Wang, Xiaolin, Zhang, Chao, Wu, Kehui, Dou, Shi Xue, Hu, Zhenpeng, and Du, Yi

Subjects

Condensed Matter - Materials Science

Abstract

The energy dispersion of fermions or bosons vanishes in momentum space if destructive quantum interference occurs in a frustrated Kagome lattice with only nearest-neighbour (NN) hopping. A discrete flat band (FB) without any dispersion is consequently formed, promising emergence of fractional quantum Hall states (FQHS) at high temperatures. Here, we report experimental realization of a FB with possible nontrivial topology in an electronic Kagome lattice on a twisted multilayer silicene. The electrons are localized in the Kagome lattice due to quantum destructive interference, and thus, their kinetic energy is quenched, which gives rise to a FB peak in density of states. A robust and pronounced one-dimensional edge state has been revealed at Kagome edge, which resides at higher energy than the FB. Our observations of the FB and the exotic edge state in electronic Kagome lattice open up the possibility towards the realization of fractional Chern insulators in two-dimensional materials.

Published

2017

36. Strain-Induced Band Engineering in Monolayer Stanene on Sb(111)

Author

Gou, Jian, Kong, Longjuan, Li, Hui, Zhong, Qing, Li, Wenbin, Cheng, Peng, Chen, Lan, and Wu, Kehui

Subjects

Condensed Matter - Materials Science

Abstract

Two-dimensional (2D) allotrope of tin with low buckled honeycomb structure, named as stanene, is proposed to be an ideal 2D topological insulator with a nontrivial gap larger than 0.1 eV. Theoretical works also pointed out the topological property of stanene occurs by strain tuning. In this letter, we report the successful realization of high quality, monolayer stanene film as well as monolayer stanene nanoribbons on Sb(111) surface by molecular beam epitaxy, providing an ideal platform to the study of stanene. More importantly, we observed a continuous evolution of the electronic bands of stanene across a nanoribbon, which are related to the strain field gradient in stanene. Our work experimentally confirmed that strain is an effective method for band engineering in stanene, which is important for fundamental research and application of stanene., Comment: 10 pages, 4 figures

Published

2017

37. Synthesis of Borophene Nanoribbons on Ag(110) Surface

Author

Zhong, Qing, Kong, Longjuan, Gou, Jian, Li, Wenbin, Sheng, Shaoxiang, Yang, Shuo, Cheng, Peng, Li, Hui, Wu, Kehui, and Chen, Lan

Subjects

Condensed Matter - Materials Science

Abstract

We present the successful synthesis of single-atom-thick borophene nanoribbons (BNRs) by self-assembly of boron on Ag(110) surface. The scanning tunneling microscopy (STM) studies reveal high quality BNRs: all the ribbons are along the [-110] direction of Ag(110), and can run across the steps on the surface. The width of ribbons is distributed in a narrow range around 10.3 nm. High resolution STM images revealed four ordered surface structures in BNRs. Combined with DFT calculations, we found that all the four structures of boron nanoribbons consist of the boron chains with different width, separated by hexagonal hole arrays. The successful synthesis of BNRs enriches the low dimensional allotrope of boron and may promote further applications of borophene, Comment: 14 pages, 3 figures

Published

2017

38. Dirac fermions in borophene

Author

Feng, Baojie, Sugino, Osamu, Liu, Ro-Ya, Zhang, Jin, Yukawa, Ryu, Kawamura, Mitsuaki, Iimori, Takushi, Kim, Howon, Hasegawa, Yukio, Li, Hui, Chen, Lan, Wu, Kehui, Kumigashira, Hiroshi, Komori, Fumio, Chiang, Tai-Chang, Meng, Sheng, and Matsuda, Iwao

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Honeycomb structures of group IV elements can host massless Dirac fermions with non-trivial Berry phases. Their potential for electronic applications has attracted great interest and spurred a broad search for new Dirac materials especially in monolayer structures. We present a detailed investigation of the \beta 12 boron sheet, which is a borophene structure that can form spontaneously on a Ag(111) surface. Our tight-binding analysis revealed that the lattice of the \beta 12-sheet could be decomposed into two triangular sublattices in a way similar to that for a honeycomb lattice, thereby hosting Dirac cones. Furthermore, each Dirac cone could be split by introducing periodic perturbations representing overlayer-substrate interactions. These unusual electronic structures were confirmed by angle-resolved photoemission spectroscopy and validated by first-principles calculations. Our results suggest monolayer boron as a new platform for realizing novel high-speed low-dissipation devices., Comment: accepted for publication in Physical Review Letters

Published

2017

39. Unraveling Enyne Bonding via Dehydrogenation–Hydrogenation Processes in On‐Surface Synthesis with Terminal Alkynes.

Author

Lyu, Yuanhao, Gao, Feng, Cheng, Peng, Chen, Lan, Klyatskaya, Svetlana, Ruben, Mario, Rosen, Johanna, Barth, Johannes V., Björk, Jonas, Wu, Kehui, and Zhang, Yi‐Qi

Subjects

CHEMICAL processes, ATOMIC force microscopy, DENSITY functional theory, CHEMICAL bonds, ATOMIC hydrogen

Abstract

On‐surface reactions of terminal alkynes in ultrahigh vacuum have attracted widespread attention due to their high technological promise. However, employing different precursors and substrate materials often intricate reaction schemes appear far from being well‐understood. Thus, recent investigations of alkyne coupling on noble metal surfaces suggest non‐dehydrogenative scenarios, contradicting earlier reports. Herein, the study employs noncontact atomic force microscopy (nc‐AFM) with high spatial resolution to conclusively characterize exemplary alkyne coupling products. Contrary to initial interpretations proposing dehydrogenative homocoupling on Ag(111), bond‐resolved AFM imaging reveals the expression of enyne motifs. Based on complementary, extensive density functional theory calculations, the pertaining reaction mechanisms are explored. It is proposed that enyne formation initiates with a direct carbon–carbon coupling between two alkyne groups, followed by surface‐assisted dehydrogenation‐hydrogenation processes. Thereby consecutive steps of atomic hydrogen cleavage, surface migration and recombination to a different carbon atom enable bridging via carbon–carbon double bonding. The new results shed light on subtle, but crucial surface‐mediated hydrogen transfer processes involved in the chemical bond formation, which are suggested to be of general relevance in on‐surface synthesis. [ABSTRACT FROM AUTHOR]

Published

2024

40. Realization of Two‐Dimensional Intrinsic Polar Metal in a Buckled Honeycomb Binary Lattice.

Author

Wang, Yihe, Li, Dong, Duan, Sisheng, Sun, Shuo, Ding, Yishui, Bussolotti, Fabio, Sun, Mingyue, Chen, Mingxi, Wang, Meng, Chen, Lan, Wu, Kehui, Goh, Kuan Eng Johnson, Wee, Andrew T. S., Zhou, Miao, Feng, Baojie, Hua, Chenqiang, Huang, Yu Li, and Chen, Wei

Published

2024

41. Realization of Material with an Atomic Ruby Lattice.

Author

Liu, Zijia, Tao, Shengdan, Liu, Huiru, Ma, Chen, Li, Panyin, Cai, Zhihao, Tian, Dacheng, He, Yu, Feng, Baojie, Chen, Lan, He, Xiaoyue, Lu, Yunhao, and Wu, Kehui

Published

2024

42. The development of a low-temperature terahertz scanning tunneling microscope based on a cryogen-free scheme.

Author

Zhang, Huaiyu, Tian, Dacheng, Zhan, Yang, Liu, Zijia, Ma, Chen, Zhang, Yuwu, Hu, Jianwei, He, Xiaoyue, Feng, Baojie, Zhang, Yiqi, Chen, Lan, Cheng, Peng, and Wu, Kehui

Subjects

PARABOLIC reflectors, VACUUM chambers, ULTRAHIGH vacuum, SPATIAL resolution, LOW temperatures

Abstract

We have developed a cryogen-free, low-temperature terahertz scanning tunneling microscope (THz-STM). This system utilizes a continuous-flow cryogen-free cooler to achieve low temperatures of ∼25 K. Meanwhile, an ultra-small ultra-high vacuum chamber results in the reduction of the distance from sample to viewport to only 4 cm. NA = 0.6 can be achieved while placing the entire optical component, including a large parabolic mirror, outside the vacuum chamber. Thus, the convenience of optical coupling is much improved without compromising the performance of STM. Based on this, we introduced THz pulses into the tunnel junction and constructed the THz-STM, achieving atomic-level spatial resolution in THz-driven current imaging and sub-picosecond (sub-ps) time resolution in autocorrelation signals during pump–probe measurements. Experimental data from various representative samples are presented to showcase the performance of the instrument, establishing it as an ideal platform for studying non-equilibrium dynamic processes at nanoscale. [ABSTRACT FROM AUTHOR]

Published

2024

43. Synthesis of bilayer borophene

Author

Chen, Caiyun, Lv, Haifeng, Zhang, Ping, Zhuo, Zhiwen, Wang, Yu, Ma, Chen, Li, Wenbin, Wang, Xuguang, Feng, Baojie, Cheng, Peng, Wu, Xiaojun, Wu, Kehui, and Chen, Lan

Published

2022

44. Gold‐template‐assisted Mechanical Exfoliation of Large‐area 2D layers Enables Efficient and Precise Construction of Moiré Superlattices

Author

Wu, Kang, primary, Wang, Hao, additional, Yang, Meng, additional, Liu, Li, additional, Sun, Zhenyu, additional, Hu, Guojing, additional, Song, Yanpeng, additional, Han, Xin, additional, Guo, Jiangang, additional, Wu, Kehui, additional, Feng, Baojie, additional, Shen, Chengmin, additional, Huang, Yuan, additional, Shi, Youguo, additional, Cheng, Zhigang, additional, Yang, Haitao, additional, Bao, Lihong, additional, Pantelides, Sokrates T., additional, and Gao, Hong‐Jun, additional

Published

2024

45. Direct and Inverse Spin Splitting Effects in Altermagnetic RuO2

Author

Guo, Yaqin, primary, Zhang, Jing, additional, Zhu, Zengtai, additional, Jiang, Yuan‐yuan, additional, Jiang, Longxing, additional, Wu, Chuangwen, additional, Dong, Jing, additional, Xu, Xing, additional, He, Wenqing, additional, He, Bin, additional, Huang, Zhiheng, additional, Du, Luojun, additional, Zhang, Guangyu, additional, Wu, Kehui, additional, Han, Xiufeng, additional, Shao, Ding‐fu, additional, Yu, Guoqiang, additional, and Wu, Hao, additional

Published

2024

46. Discovery of two-dimensional Dirac nodal line fermions in monolayer Cu2Si

Author

Feng, Baojie, Fu, Botao, Kasamatsu, Shusuke, Ito, Suguru, Cheng, Peng, Liu, Cheng-Cheng, Feng, Ya, Wu, Shilong, Mahatha, Sanjoy K., Sheverdyaeva, Polina, Moras, Paolo, Arita, Masashi, Sugino, Osamu, Chiang, Tai-Chang, Shimada, Kenya, Miyamoto, Koji, Okuda, Taichi, Wu, Kehui, Chen, Lan, Yao, Yugui, and Matsuda, Iwao

Subjects

Condensed Matter - Materials Science

Abstract

Topological nodal line semimetals, a novel quantum state of materials, possess topologically nontrivial valence and conduction bands that touch at a line near the Fermi level. The exotic band structure can lead to various novel properties, such as long-range Coulomb interaction and flat Landau levels. Recently, topological nodal lines have been observed in several bulk materials, such as PtSn4, ZrSiS, TlTaSe2 and PbTaSe2. However, in two-dimensional materials, experimental research on nodal line fermions is still lacking. Here, we report the discovery of two-dimensional Dirac nodal line fermions in monolayer Cu2Si based on combined theoretical calculations and angle-resolved photoemission spectroscopy measurements. The Dirac nodal lines in Cu2Si form two concentric loops centred around the {\Gamma} point and are protected by mirror reflection symmetry. Our results establish Cu2Si as a new platform to study the novel physical properties in two-dimensional Dirac materials and provide new opportunities to realize high-speed low-dissipation devices., Comment: Accepted in Nature Communications

Published

2016

47. Point defects in epitaxial silicene on Ag(111) surface

Author

Liu, Hongsheng, Feng, Haifeng, Du, Yi, Chen, Jian, Wu, Kehui, and Zhao, Jijun

Subjects

Condensed Matter - Materials Science

Abstract

Silicene, a counterpart of graphene, has achieved rapid development due to its exotic electronic properties and excellent compatibility with the mature silicon-based semiconductor technology. Its low room-temperature mobility of about 100 cm2V-1s-1, however, inhibits device applications such as in field-effect transistors. Generally, defects and grain boundaries would act as scattering centers and thus reduce the carrier mobility. In this paper, the morphologies of various point defects in epitaxial silicene on Ag(111) surfaces have been systematically investigated using first-principles calculations combined with experimental scanning tunneling microscope (STM) observations. The STM signatures for various defects in epitaxial silicene on Ag(111) surface are identified. In particular, the formation energies of point defects in Ag(111)-supported silicene sheets show an interesting dependence on the superstructures, which, in turn, may have implications for controlling the defect density during the synthesis of silicene. Through estimating the concentrations of various point defects in different silicene superstructures, the mystery of the defective appearance of v13*v13 silicene in experiments is revealed, and 4*4 silicene sheet is thought to be the most suitable structure for future device applications., Comment: 29 pages, 14 figures

Published

2015

48. Direct Evidence of Metallic Bands in a Monolayer Boron Sheet

Author

Feng, Baojie, Zhang, Jin, Liu, Ro-Ya, Takushi, Iimori, Lian, Chao, Chen, Lan, Wu, Kehui, Li, Hui, Meng, Sheng, Komori, Fumio, and Matsuda, Iwao

Subjects

Condensed Matter - Materials Science

Abstract

The search for metallic boron allotropes has attracted great attention in the past decades and recent theoretical works predict the existence of metallicity in monolayer boron. Here, we synthesize the \b{eta}12-sheet monolayer boron on a Ag(111) surface and confirm the presence of metallic boron-derived bands using angle-resolved photoemission spectroscopy. The Fermi surface is composed of one electron pocket at the S point and a pair of hole pockets near the X point, which is supported by the first-principles calculations. The metallic boron allotrope in \b{eta}12 sheet opens the way to novel physics and chemistry in material science., Comment: 5 pages, 4 figures

Published

2015

49. Experimental Realization of Two-Dimensional Boron Sheets

Author

Feng, Baojie, Zhang, Jin, Zhong, Qing, Li, Wenbin, Li, Shuai, Li, Hui, Cheng, Peng, Meng, Sheng, Chen, Lan, and Wu, Kehui

Subjects

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

Abstract

Boron is the fifth element in the periodic table and possesses rich chemistry second only to carbon. A striking feature of boron is that B12 icosahedral cages occur as the building blocks in bulk boron and many boron compounds. This is in contrast to its neighboring element, carbon, which prefers 2D layered structure (graphite) in its bulk form. On the other hand, boron clusters of medium size have been predicted to be planar or quasi-planar, such as B12+ , B13+, B19-, B36, and so on. This is also in contrast to carbon clusters which exhibit various cage structures (fullerenes). Therefore, boron and carbon can be viewed as a set of complementary chemical systems in their bulk and cluster structures. Now, with the boom of graphene, an intriguing question is that whether boron can also form a monoatomic-layer 2D sheet structure? Here, we report the first successful experimental realization of 2D boron sheets. We have revealed two types of boron sheet structures, corresponding to a triangular boron lattice with different arrangements of the hexagonal holes. Moreover, our boron sheets were found to be relatively stable against oxidization, and interacts only weekly with the substrate. The realization of such a long expected 2D boron sheet could open a door toward boron electronics, in analogous to the carbon electronics based on graphene., Comment: 4 figures

Published

2015

50. Quantized one-dimensional edge channels with strong spin-orbit coupling in 3D topological insulators

Author

Kastl, Christoph, Seifert, Paul, He, Xiaoyue, Wu, Kehui, Li, Yongqing, and Holleitner, Alexander

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A strong coupling between the electron spin and its motion is one of the prerequisites of spin-based data storage and electronics. A major obstacle is to find spin-orbit coupled materials where the electron spin can be probed and manipulated on macroscopic length scales, for instance across the gate channel of a spin-transistor. Here, we report on millimeter-scale edge channels with a conductance quantized at a single quantum 1 $\times$ $e^2/h$ at zero magnetic field. The quantum transport is found at the lateral edges of three-dimensional topological insulators made of bismuth chalcogenides. The data are explained by a lateral, one-dimensional quantum confinement of non-topological surface states with a strong Rashba spin-orbit coupling. This edge transport can be switched on and off by an electrostatic field-effect. Our results are fundamentally different from an edge transport in quantum spin Hall insulators and quantum anomalous Hall insula-tors.

Published

2015