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128 results on '"Yuan, Jiaren"'

1. Topological skyrmions in monolayer multiferroic MoPtGe2S6

Author

Fu, Zuxin, Hao, Kuanrong, Guo, Min, He, Jingjing, Yan, Xiaohong, Zhou, Yangbo, Shen, Lei, and Yuan, Jiaren

Subjects
Condensed Matter - Materials Science
Abstract

Two-dimensional (2D) multiferroic materials with coexisting ferroelectricity and ferromagnetism have garnered substantial attention for their intriguing physical properties and diverse promising applications in spintronics. For example, multiferroic materials with electronically controlled broken central symmetry provide a versatile platform for designing and manipulating topological skyrmions and diverse spintronic applications. Here, we investigate the complex magnetic properties of room-temerature multiferroic material MoPtGe2S6 and its electrical control of topological skyrmions using first-principles calculations and atomistic micromagnetic simulations. A sizable Dzyaloshinskii-Moriya interaction (DMI) (2.1 meV) is found in the multiferroic material MoPtGe2S6 with an electrically polarized ground state. The magnetic skyrmions can be stabilized in monolayer MoPtGe2S6 under zero magnetic field, and the chirality of skyrmions can be reversed with electric field-induced flipping of electrical polarization due to the reversed chirality of the DMI. Furthermore, an external magnetic fielc can reverse the magnetization direction and topological charge of the skyrmions as well as tune the size of skyrmions. These results demonstrate that the monolayer MoPtGe2S6 can enrich the 2D skyrmion community and pave the way for electronically controlled spintronic devices., Comment: 24 pages, 7 figures

Published
2024

2. Magnetic Transition in Monolayer VSe2 via Interface Hybridization

Author

Zhang, Wen, Zhang, Lei, Wong, Ping Kwan Johnny, Yuan, Jiaren, Vinai, Giovanni, Torelli, Piero, van der Laan, Gerrit, Feng, Yuan Ping, and Wee, Andrew Thye Shen

Subjects
Condensed Matter - Materials Science
Abstract

Magnetism in monolayer (ML) VSe2 has attracted broad interest in spintronics while existing reports have not reached consensus. Using element-specific X-ray magnetic circular dichroism, a magnetic transition in ML VSe2 has been demonstrated at the contamination-free interface between Co and VSe2. Via interfacial hybridization with Co atomic overlayer, a magnetic moment of about 0.4 uB per V atom in ML VSe2 is revealed, approaching values predicted by previous theoretical calculations. Promotion of the ferromagnetism in ML VSe2 is accompanied by its antiferromagnetic coupling to Co and a reduction in the spin moment of Co. In comparison to the absence of this interface-induced ferromagnetism at the Fe/MLMoSe2 interface, these findings at the Co/ML-VSe2 interface provide clear proof that the ML VSe2, initially with magnetic disorder, is on the verge of magnetic transition.

Published
2022
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3. Squeezed metallic droplet with tunable Kubo gap and charge injection in transition metal dichalcogenides

Author

Yuan, Jiaren, Chen, Yuanping, Xie, Yuee, Zhang, Xiaoyu, Rao, Dewei, Guo, Yandong, Yan, Xiaohong, Feng, Yuanping, and Cai, Yongqing

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

Shrinking the size of a bulk metal into nanoscale leads to the discreteness of electronic energy levels, the so-called Kubo gap. Renormalization of the electronic properties with a tunable and size-dependent Kubo gap renders fascinating photon emission and electron tunneling. In contrast with usual three-dimensional (3D) metal clusters, here we demonstrate that Kubo gap can be achieved with a two-dimensional (2D) metallic transition metal dichalcogenide (i.e., 1T'-phase MoTe2) nanocluster embedded in a semiconducting polymorph (i.e., 1H-phase MoTe2). Such a 1T'-1H MoTe2 nanodomain resembles a 3D metallic droplet squeezed in a 2D space which shows a strong polarization catastrophe while simultaneously maintains its bond integrity which is absent in traditional delta-gapped 3D clusters. The weak screening of the host 2D MoTe2 leads to photon emission of such pseudo-metallic systems and a ballistic injection of carriers in the 1T'-1H-1T' homojunctions which may find applications in sensors and 2D reconfigurable devices.

Published
2022
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4. Protected valley states and generation of valley- and spin-polarized current in monolayer MA2Z4

Author

Yuan, Jiaren, Wei, Qingyuan, Sun, Minglei, Yan, Xiaohong, Cai, Yongqing, Shen, Lei, and Schwingenschlögl, Udo

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter
Abstract

The optical selection rules obeyed by two-dimensional materials with spin-valley coupling enable the selective excitation of carriers. We show that six members of the monolayer MA2Z4 (M = Mo and W; A = C, Si, and Ge; Z = N, P, and As) family are direct band-gap semiconductors with protected valley states and that circularly polarized infrared light can induce valley-selective inter-band transitions. Our optovalleytronic device demonstrates a close to 100% valley- and spin-polarized current under in-plane bias and circularly polarized infrared light, which can be exploited to encode, process, and store information., Comment: 6 figures

Published
2021
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5. Bilayer twisting as a mean to isolate connected flat bands in a Kagome lattice through Wigner crystallization

Author

Wu, Jing, Xie, Yuee, Chen, Mingxing, Yuan, Jiaren, Yan, Xiaohong, Zhang, Shengbai, and Chen, Yuanping

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Quantum Physics
Abstract

The physics of flat band is novel and rich but difficult to access. In this regard, recently twisting of bilayer van der Waals (vdW)-bounded two-dimensional (2D) materials has attracted much attention, because the reduction of Brillouin zone will eventually lead to a diminishing kinetic energy. Alternatively, one may start with a 2D Kagome lattice, which already possesses flat bands at the Fermi level, but unfortunately these bands connect quadratically to other (dispersive) bands, leading to undesirable effects. Here, we propose, by first-principles calculation and tight-binding modeling, that the same bilayer twisting approach can be used to isolate the Kagome flat bands. As the starting kinetic energy is already vanishingly small, the interlayer vdW potential is always sufficiently large irrespective of the twisting angle. As such the electronic states in the (connected) flat bands become unstable against a spontaneous Wigner crystallization, which is expected to have interesting interplays with other flat-band phenomena such as novel superconductivity and anomalous quantum Hall effect.

Published
2021
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9. Origin and Large Enhancement of Large Spin Hall Angle in Weyl Semimetals LaAl$X$ ($X$=Si, Ge)

Author

Ng, Truman, Luo, Yongzheng, Yuan, Jiaren, Wu, Yihong, Yang, Hyunsoo, and Shen, Lei

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

We study the origin of the strong spin Hall effect (SHE) in a recently discovered family of Weyl semimetals, LaAl$X$ ($X$=Si, Ge) via a first-principles approach with maximally localized Wannier functions. We show that the strong intrinsic SHE in LaAl$X$ originates from the multiple slight anticrossings of nodal lines and points near $E_F$ due to their high mirror symmetry and large spin-orbit interaction. It is further found that both electrical and thermal means can enhance the spin Hall conductivity ($\sigma_{SH}$). However, the former also increases the electrical conductivity ($\sigma_{c}$), while the latter decreases it. As a result, the independent tuning of $\sigma_{SH}$ and $\sigma_{c}$ by thermal means can enhance the spin Hall angle (proportional to $\frac{\sigma_{SH}}{\sigma_{c}}$), a figure of merit of charge-to-spin current interconversion of spin-orbit torque devices. The underlying physics of such independent changes of the spin Hall and electrical conductivity by thermal means is revealed through the band-resolved and $k$-resolved spin Berry curvature. Our finding offers a new way in the search of high SHA materials for room-temperature spin-orbitronics applications., Comment: 21 pages, 6 figures

Published
2020
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11. In-situ study of oxygen exposure effect on spin-orbit torque in Pt/Co bilayers in ultrahigh vacuum

Author

Xie, Hang, Yuan, Jiaren, Luo, Ziyan, Yang, Yumeng, and Wu, Yihong

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Oxygen incorporation has been reported to increase the current-induced spin-orbit torque in ferromagnetic heterostructures, but the underlying mechanism is still under active debate. Here, we report on an in-situ study of the oxygen exposure effect on spin-orbit torque in Pt/Co bilayers via controlled oxygen exposure, Co and Mg deposition, and electrical measurements in ultrahigh vacuum. We show that the oxygen exposure on Pt/Co indeed leads to an increase of spin-orbit torque, but the enhancement is not as large as those reported previously. Similar enhancement of spin-orbit torque is also observed after the deposition of an MgO capping layer. The results of ab initio calculations on the Rashba splitting of Pt/Co and Pt/Co/O suggest that the enhancement is due to enhanced Rashba-Edelstein effect by surface-adsorbed oxygen. Our findings shed some light on the varying roles of oxygen in modifying the spin torque efficiency reported previously., Comment: 25 pages, 6 figures

Published
2019

12. Intrinsic skyrmions in monolayer Janus magnets

Author

Yuan, Jiaren, Yang, Yumeng, Cai, yongqing, Wu, Yihong, Chen, Yuanping, Yan, Xiaohong, Xu, Guiyin, and Shen, Lei

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Skyrmions are localized solitonic spin textures with protected topology, which are promising as information carriers in ultra-dense and energy-efficient logic and memory devices. Recently, magnetic skyrmions have been observed in magnetic thin films, and are stabilized by the extrinsic interfacial Dzyaloshinskii-Moriya interaction (DMI) and/or external magnetic fields. The specific effects in magnetic monolayer materials have not been thoroughly studied. Here, we investigate the intrinsic magnetic skyrmions in a family of monolayer Janus van der Waals magnets, MnSTe, MnSeTe, VSeTe, and MnSSe, by the first-principles calculations combined with the micromagnetic simulations. The monolayer Janus MnSTe, MnSeTe, and VSeTe with out-of-plane geometric asymmetry and strong spin-orbit coupling (SOC) have a large intrinsic DMI, which could stabilize a sub-50 nm intrinsic skyrmions in monolayer MnSTe and MnSeTe at zero magnetic field. While monolayer VSeTe with in-plane easy axis forms magnetic domain rather than skyrmions. Moreover, the size and shape of skyrmions can be tuned by an external magnetic field. Therefore, our work motivates a new vista for seeking intrinsic skyrmions in atomic-scale magnets., Comment: 11 figures

Published
2019
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16. Ferromagnet/Two-Dimensional Semiconducting Transition-Metal Dichalcogenide Interface with Perpendicular Magnetic Anisotropy

Author

Zhang, Wen, Wong, Ping Kwan Johnny, Zhou, Xiaochao, Rath, Ashutosh, Huang, Zhaocong, Wang, Hongyu, Morton, Simon A, Yuan, Jiaren, Zhang, Lei, Chua, Rebekah, Zeng, Shengwei, Liu, Er, Xu, Feng, Ariando, Chua, Daniel HC, Feng, Yuan Ping, van der Laan, Gerrit, Pennycook, Stephen J, Zhai, Ya, and Wee, Andrew TS

Subjects
Quantum Physics, Engineering, Physical Sciences, Condensed Matter Physics, X-ray magnetic circular dichroism, anisotropic orbital moment, interface, perpendicular magnetic anisotropy, spintronics, transition-metal dichalcogenides, two-dimensional materials, Nanoscience & Nanotechnology
Abstract

Ferromagnet/two-dimensional transition-metal dichalcogenide (FM/2D TMD) interfaces provide attractive opportunities to push magnetic information storage to the atomically thin limit. Existing work has focused on FMs contacted with mechanically exfoliated or chemically vapor-deposition-grown TMDs, where clean interfaces cannot be guaranteed. Here, we report a reliable way to achieve contamination-free interfaces between ferromagnetic CoFeB and molecular-beam epitaxial MoSe2. We show a spin reorientation arising from the interface, leading to a perpendicular magnetic anisotropy (PMA), and reveal the CoFeB/2D MoSe2 interface allowing for the PMA development in a broader CoFeB thickness-range than common systems such as CoFeB/MgO. Using X-ray magnetic circular dichroism analysis, we attribute generation of this PMA to interfacial d-d hybridization and deduce a general rule to enhance its magnitude. We also demonstrate favorable magnetic softness and considerable magnetic moment preserved at the interface and theoretically predict the interfacial band matching for spin filtering. Our work highlights the CoFeB/2D MoSe2 interface as a promising platform for examination of TMD-based spintronic applications and might stimulate further development with other combinations of FM/2D TMD interfaces.

Published
2019

19. Unveiling the role of Co-O-Mg bond in magnetic anisotropy of Pt/Co/MgO using atomically controlled deposition and in-situ electrical measurement

Author

Yang, Yumeng, Yuan, Jiaren, Qi, Long, Wang, Ying, Xu, Yanjun, Wang, Xiaowei, Feng, Yuanping, Xu, Baoxi, Shen, Lei, and Wu, Yihong

Subjects
Condensed Matter - Materials Science
Abstract

Despite the crucial role of interfacial perpendicular magnetic anisotropy in Co(Fe)/MgO based magnetic tunnel junction, the underlying mechanism is still being debated. Here, we report an anatomical study of oxygen and Mg effect on Pt/Co bilayers through repeated in-situ anomalous Hall effect measurements, controlled oxygen exposure and Mg deposition in an ultrahigh vacuum system. We found that chemisorbed oxygen not only quenches the effective magnetic moment of the Co surface layer, but also softens its magnetic anisotropy. However, a subsequent Mg dusting on the oxygen pre-exposed Pt/Co surface can recover the magnetic anisotropy. The ab initio calculations on the exchange splitting and orbital hybridization near the Fermi level give a clear physical explanation of the experimental observations. Our results suggest that Co(Fe)-O-M bond plays a more important role than the widely perceived Co(Fe)-O bond does in realizing interfacial perpendicular magnetic anisotropy in Co(Fe)/MgO heterostructures.

Published
2017
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20. Evolution from Topological Nodal Points to Nodal Line: Realized in Fused Carbon Allotrope.

Author

Xing, Jinhui, Yue, Wentao, Yuan, Jiaren, Zhang, Lizhi, Wei, Yingcong, Zhang, Lichuan, Xie, Yuee, and Chen, Yuanping

Subjects
PHASE transitions, TOPOLOGICAL property, SEMIMETALS, PHONONS, SYMMETRY
Abstract

Herein, via first‐principle calculations and theoretical analysis, a new Dirac semimetal carbon system called C32, which is composed of pentagonal, hexagonal, heptagonal, and octagonal carbon rings is systematically investigated. The stability of C32 is verified by calculating the phonon dispersion, elastic constants, etc., and an appropriate pathway for experimental synthesis is proposed. Besides, it is discovered that the system holds the quadruple rotation and inversion symmetry, resulting in the emergence of eight twisted Dirac cones (D1 and D2) with a highly anisotropic Fermi velocity from 3.83 × 105 to 8.96 × 105 m s−1 along different k directions. To substantiate the semimetallic nature of C32, its nontrivial topological properties are confirmed through the presence of topologically protected edge states, and the nonzero ℤ2 topological invariant. More importantly, by introducing biaxial strain, it is uncovered that Dirac cones can gradually evolve into a nodal line, and the perfect nodal line can be obtained when the biaxial strain is 13.3%. Furthermore, by constructing the tight‐binding model, the appearance of the Dirac cone is perfectly repeated and its evolution into the nodal line under biaxial strain is explained. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Spectroscopic Analysis on Different Stacking Configurations of Multilayered MoSe 2.

Author

Hu, Xiang, Wang, Yong, Yuan, Jiaren, Liao, Xiaxia, and Zhou, Yangbo

Subjects
SECOND harmonic generation, CHEMICAL vapor deposition, RAMAN spectroscopy, TRANSITION metals, LUMINESCENCE
Abstract

Transition metal dichalcogenides (TMDs) are drawing significant attention due to their intriguing photoelectric properties, and these interesting properties are closely related to the number of layers. Obtaining layer-controlled and high-quality TMD is still a challenge. In this context, we use the salt-assisted chemical vapor deposition to grow multilayered MoSe2 flake and characterize it by Raman spectroscopy, second harmonic generation, and photon luminescence. Spectroscopic analysis is an effective way to characterize the stacking order and optoelectronic properties of two-dimensional materials. Notably, the corresponding mapping reflects the film quality and homogeneity. We found that the grown continuous monolayer, bilayer, and trilayer of MoSe2 sheets with different stacking orders exhibit distinctive features. For bilayer MoSe2, the most stable stacking configurations are the AA' and AB order. And the uniformity of the spectroscopy maps demonstrates the high quality of the stacked MoSe2 sheets. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Spin Hall effect modulated by an electric field in asymmetric two-dimensional MoSiAs2Se.

Author

Xing, Jinhui, Wu, Chao, Li, Shiqi, Chen, Yuanping, Zhang, Lizhi, Xie, Yuee, Yuan, Jiaren, and Zhang, Lichuan

Abstract

Spin current generation from charge current in nonmagnetic materials promises an energy-efficient scheme for manipulating magnetization in spintronic devices. In some asymmetric two-dimensional (2D) materials, the Rashba and valley effects coexist owing to strong spin–orbit coupling (SOC), which induces the spin Hall effect due to spin-momentum locking of both effects. Herein, we propose a new Janus structure MoSiAs2Se with both valley physics and the Rashba effect and reveal an effective way to modulate the properties of this structure. The results demonstrated that applying an external electric field is an effective means to modulating the electronic properties of MoSiAs2Se, leading to both type I–II phase transitions and semiconductor–metal phase transitions. Furthermore, the coexistence of the Rashba and valley effects in monolayer MoSiAs2Se contributes to the spin Hall effect (SHE). The magnitude and direction of spin Hall conductivity can also be manipulated with an out-of-plane electric field. Our results enrich the physics and materials of the Rashba and valley systems, opening new opportunities for the applications of 2D Janus materials in spintronic devices. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Electrostatic Gating of Spin Dynamics of a Quasi-2D Kagome Magnet

Author

Li, Zhidong, primary, Zhang, Ruifu, additional, Shan, Jun, additional, Alahmed, Laith, additional, Xu, Ailing, additional, Chen, Yuanping, additional, Yuan, Jiaren, additional, Cheng, Xiaomin, additional, Miao, Xiangshui, additional, Wen, Jiajia, additional, Mokrousov, Yuriy, additional, Lee, Young S., additional, Zhang, Lichuan, additional, and Li, Peng, additional

Published
2024
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33. Cu2O/Cu2S microstructure regulation towards high efficiency photocatalytic hydrogen production and its theoretical mechanism analysis.

Author

Qiao, Fen, Qian, Sen, Liu, Wenjie, Zhou, Taihang, Yang, Jing, Zhao, Jikang, and Yuan, Jiaren

Subjects
OXIDATION-reduction reaction, CHARGE transfer, SULFIDATION, X-ray diffraction, HYDROGEN production, MICROSTRUCTURE
Abstract

Cu2O with a cubic structure was prepared by a water bath method, and then a Cu2O/Cu2S core–shell material was obtained by the redox reaction of Cu2O and Na2S with the prepared cubic Cu2O as a template and Na2S·9H2O solution as the reaction solution. At the same time, the effect of sulfidization time on the Cu2O/Cu2S structure and photohydrogen production performance was studied. The structure of the samples was further confirmed and characterized through SEM, HRTEM, XRD and XPS. The photohydrogen production properties of the Cu2O/Cu2S composites with different morphologies were tested. The flower-shaped hollow structure of Cu2O/Cu2S can be obtained by proper sulfidization, and the hydrogen production can reach 1076.95 μmol g−1 after 5 h of illumination. Then, through photocurrent response and impedance spectrum tests and DFT calculations, it is proved that the Cu2O/Cu2S heterostructure can effectively improve the photoresponse ability and carrier transport properties. It was confirmed that the interfacial charge transfer in Cu2O/Cu2S helped increase the photocatalytic hydrogen production performance. [ABSTRACT FROM AUTHOR]

Published
2023
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38. Strain Modulation of Electronic Properties in Monolayer SnP 2 S 6 and GeP 2 S 6.

Author

Zhou, Junlei, Gu, Yuzhou, Xie, Yue-E, Qiao, Fen, Yuan, Jiaren, He, Jingjing, Wang, Sake, Li, Yangsheng, and Zhou, Yangbo

Subjects
MONOMOLECULAR films, ELECTRONIC modulation, CONDUCTION bands, VALENCE bands, OPTOELECTRONIC devices, POLAR effects (Chemistry)
Abstract

In recent years, two-dimensional (2D) materials have attracted significant attention due to their distinctive properties, including exceptional mechanical flexibility and tunable electronic properties. Via the first-principles calculation, we investigate the effect of strain on the electronic properties of monolayer SnP2S6 and GeP2S6. We find that monolayer SnP2S6 is an indirect bandgap semiconductor, while monolayer GeP2S6 is a direct bandgap semiconductor. Notably, under uniform biaxial strains, SnP2S6 undergoes an indirect-to-direct bandgap transition at 4.0% biaxial compressive strains, while GeP2S6 exhibits a direct-to-indirect transition at 2.0% biaxial tensile strain. The changes in the conduction band edge can be attributed to the high-symmetry point Γ being more sensitive to strain than K. Thus, the relocation of the conduction band and valence band edges in monolayer SnP2S6 and GeP2S6 induces a direct-to-indirect and indirect-to-direct bandgap transition, respectively. Consequently, the strain is an effective band engineering scheme which is crucial for the design and development of next-generation nanoelectronic and optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published
2023
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42. Zincophilic Polymer Semiconductor as Multifunctional Protective Layer Enables Dendrite-Free Zinc Metal Anodes

Author

Jiang, Jiangmin, primary, Pan, Zhenghui, additional, Yuan, Jiaren, additional, Shan, Jun, additional, Chen, Chenglong, additional, Li, Shaopeng, additional, Xu, Hai, additional, Chen, Yaxin, additional, Zhuang, Quanchao, additional, Ju, Zhicheng, additional, Dou, Hui, additional, Zhang, Xiaogang, additional, and Wang, John, additional

Published
2022
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44. Facile Synthesis of Medium‐Entropy Metal Sulfides as High‐Efficiency Electrocatalysts toward Oxygen Evolution Reaction.

Author

Wu, Lei, Shen, Xiaoping, Ji, Zhenyuan, Yuan, Jiaren, Yang, Shaokang, Zhu, Guoxing, Chen, Lizhi, Kong, Lirong, and Zhou, Hongbo

Subjects
OXYGEN evolution reactions, ELECTROCATALYSTS, METAL sulfides, HYDROGEN as fuel, CLEAN energy
Abstract

Developing highly efficient and durable electrocatalysts toward oxygen evolution reaction (OER) is an urgent demand to produce clean hydrogen energy. In this study, a series of medium‐entropy metal sulfides (MEMS) of (NiFeCoX)3S4 (where X = Mn, Cr, Zn) are synthesized by a facile one‐pot solvothermal strategy using molecular precursors. Benefiting from the multiple‐metal synergistic effect and the low crystallinity, these MEMS show significantly enhanced electrocatalytic OER activity compared with the binary‐metal (NiFe)3S4 and ternary‐metal (NiFeCo)3S4 counterparts. Especially, (NiFeCoMn)3S4 delivers a low overpotential of 289 mV at 10 mA cm−2, a decent Tafel slope of 75.6 mV dec−1 and robust catalytic stability in alkaline medium, outperforming the costly IrO2 benchmark electrocatalyst and the majority of the reported metal sulfide‐based electrocatalysts until now. These MEMS with facile synthesis and excellent electrocatalytic performance bring a great opportunity to design desirable electrocatalysts for practical application. [ABSTRACT FROM AUTHOR]

Published
2023
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45. Quasi-One-Dimensional ZrS3Nanoflakes for Broadband and Polarized Photodetection with High Tuning Flexibility

Author

Chen, Feng, Liu, Guangjian, Xiao, Zhenyang, Zhou, Hua, Fei, Linfeng, Wan, Siyuan, Liao, Xiaxia, Yuan, Jiaren, and Zhou, Yangbo

Abstract

Two-dimensional (2D) layered materials with low crystal symmetries have exhibited unique anisotropic physical properties. Here, we report systematic studies on the photoresponse of field effect transistors (FETs) fabricated using quasi-one-dimensional ZrS3nanoflakes. The as-fabricated phototransistors exhibit a broadband photocurrent response from ultraviolet to visible regions, where the responsivity and detectivity can be enhanced via additional gate voltages. Furthermore, benefiting from the strong in-plane anisotropy of ZrS3, we observe a gate-voltage and illumination wavelength-dependent polarized photocurrent response, while its sub-millisecond-time response speed is also polarization-dependent. Our results demonstrate the flexible tunability of photodetectors based on anisotropic layered semiconductors, which substantially broadens the application of low symmetry layered materials in polarization-sensitive optoelectronic devices.

Published
2023
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49. Chip-Level Integration of Covalent Organic Frameworks for Trace Benzene Sensing

Author

Yuan, Hongye, primary, Li, Nanxi, additional, Linghu, Jiajun, additional, Dong, Jinqiao, additional, Wang, Yuxiang, additional, Karmakar, Avishek, additional, Yuan, Jiaren, additional, Li, Mengsha, additional, Buenconsejo, Pio John S., additional, Liu, Guoliang, additional, Cai, Hong, additional, Pennycook, Stephen John, additional, Singh, Navab, additional, and Zhao, Dan, additional

Published
2020
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