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1. Large Anomalous Hall Effect at Room Temperature in a Fermi-Level-Tuned Kagome Antiferromagnet

Author

Song, Linxuan, Zhou, Feng, Li, Hang, Ding, Bei, Li, Xue, Xi, Xuekui, Yao, Yuan, Lau, Yong-Chang, and Wang, Wenhong

Subjects
Condensed Matter - Materials Science
Abstract

The recent discoveries of surperisingly large anomalous Hall effect in chiral antiderromagnets have triggered extensive research efforts in various fields, ranging from topological condensed-matter physics to antiferromagnetic spintronics, and energy harvesting technology. However, such AHE-hosting antiferromagnetic materials are rare in nature. Herein, we demonstrate that Mn2.4Ga, a Fermi-level-tuned kagome antiferromagnet, has a large anomalous Hall conductivity of about 150 {\Omega}-1cm-1 at room temperature that surpasses the usual high values (i.e.,20-50 {\Omega}-1cm-1) observed so far in two outstanding kagome antiferromagnets, Mn3Sn and Mn3Ge. The spin triangular structure of Mn2.4Ga guarantees a nonzero Berry curvature while generates only a weak net moment in the kagome plane.Moreover, the anomalous Hall conductivity exhibits a sign reversal with the rotation of a small magnetic field, which can be ascribed to the field-controlled chirality of the spin triangular structure. Our theoretical calculation indicate that the large AHE in Mn2.4Ga originates from a significantly enhanced Berry curvature associated wiht the tuning of the Fermi level close to the Weyl points. These properties, together with the ability to manipulate moment orientations using a moderate external magnetic field, make Mn2.4Ga extremely exciting for future antiferromagnetic spintronics., Comment: This article has been accepted by the Advanced Functional Materials

Published
2024
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2. Observation of short-period helical spin order and magnetic transition in a non-chiral centrosymmetric helimagnet

Author

Ding, Bei, Liu, Jun, Li, Hang, Liang, Jinjing, Chen, Jie, Li, Zefang, Li, Xue, Xi, Xuekui, Cheng, Zhenxiang, Wang, Jianli, Yao, Yuan, and Wang, Wenhong

Subjects
Condensed Matter - Materials Science
Abstract

The search for materials exhibiting nanoscale spiral order continues to be fuelled by the promise of emergent inductors. Although such spin textures have been reported in many materials, most of them exhibit long periods or are limited to operate far below room temperature. Here, we present the real-space observation of an ordered helical spin order with a period of 3.2 nm in a non-chiral centrosymmetric helimagnet MnCoSi at room temperature via multi-angle and multi-azimuth approach of Lorentz transmission electron microscopy (TEM). A magnetic transition from the ordered helical spin order to a cycloidal spin order below 228 K is clearly revealed by in situ neutron powder diffraction and Lorentz TEM, which is closely correlated with temperature-induced variation in magneto-crystalline anisotropy. These results reveal the origin of spiral ordered spin textures in non-chiral centrosymmetric helimagnet, which can serve as a new strategy for searching materials with nanoscale spin order with potential applications in emergent electromagnetism., Comment: 18 pages, 5 figures

Published
2022

3. Coherent spin rotation-induced zero thermal expansion in MnCoSi-based spiral magnets

Author

Liu, Jun, Ding, Bei, Yao, Yuan, Xi, Xuekui, Cheng, Zhenxiang, Wang, Jianli, Wang, Chin-wei, Wu, Guangheng, and Wang, Wenhong

Subjects
Condensed Matter - Materials Science
Abstract

Materials exhibiting zero thermal expansion (ZTE), namely, volume invariance during temperature change, can resist thermal shock and are highly desired in modern industries as high-precision components. However, pure ZTE materials are rare, especially those that are metallic. Here, we report the discovery of a pure metallic ZTE material: an orthorhombic Mn1-xNixCoSi spiral magnet. The introduction of Ni can efficiently enhance the ferromagnetic exchange interaction and construct the transition from a spiral magnetic state to a ferromagnetic-like state in MnCoSi-based alloys. Systematic in situ neutron powder diffraction revealed a new cycloidal spiral magnetic structure in bc plane at ground state which would transform to the helical spiral in the ab plane with increasing temperature. Combined with Lorentz transmission electron microscopy techniques, the cycloidal and helical spin order coherently rotated at varying periods along the c axis during the magnetic transition. This spin rotation drove the continuous movement of the coupled crystalline lattice and induced a large negative thermal expansion along the a axis, eventually leading to a wide-temperature ZTE effect. Our work not only introduces a new ZTE alloy but also presents a new mechanism by which to discover or design ZTE magnets., Comment: 22 pages, 8 figures

Published
2021

5. Magnetic anisotropy and critical behavior of the quaternary van der Waals ferromagnetic material $\bf CrGe_{\delta}Si_{1-\delta}Te_3$

Author

Li, Zefang, Li, Xue, Ding, Bei, Li, Hang, Yao, Yuan, Xi, Xuekui, and Wang, Wenhong

Subjects
Physics - Applied Physics
Abstract

Recently, two-dimensional ferromagnetism in the family of Chromium compounds $\rm CrXTe_3 (X=Si, Ge)$ has attracted a broad research interest. Despite the structural similarity in $\rm CrTe_6$ octahedra, the size effect of inserted Ge or Si dimer contributes to significant differences in magnetism. Here, we report a new quaternary van der Waals ferromagnetic material $\rm CrGe_{\delta}Si_{1-\delta}Te_3$ synthesized by flux method. Ge substitution in Si site results in the lattice expansion, further increasing the Curie temperature and reducing the magnetic anisotropy. The critical behavior of $\rm Cr_{0.96}Ge_{0.17}Si_{0.82}Te_3$ has been studied by specific heat as well as magnetization measurements. And the extracted critical exponents are self-consistent and well-obeying the scaling laws, which are closer to the 2D Ising model with interaction decaying as $J(r)\approx r^{-3.44}$.

Published
2021
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6. On the anomalous low-resistance state and exceptional Hall component in hard-magnetic Weyl nanoflakes

Author

Zeng, Qingqi, Gu, Gangxu, Shi, Gang, Shen, Jianlei, Ding, Bei, Zhang, Shu, Xi, Xuekui, Felser, Claudia, Li, Yongqing, and Liu, Enke

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

Magnetic topological materials, which combine magnetism and topology, are expected to host emerging topological states and exotic quantum phenomena. In this study, with the aid of greatly enhanced coercive fields in high-quality nanoflakes of the magnetic Weyl semimetal Co3Sn2S2, we investigate anomalous electronic transport properties that are difficult to reveal in bulk Co3Sn2S2 or other magnetic materials. When the magnetization is antiparallel to the applied magnetic field, the low longitudinal resistance state occurs, which is in sharp contrast to the high resistance state for the parallel case. Meanwhile, an exceptional Hall component that can be up to three times larger than conventional anomalous Hall resistivity is also observed for transverse transport. These anomalous transport behaviors can be further understood by considering nonlinear magnetic textures and the chiral magnetic field associated with Weyl fermions, extending the longitudinal and transverse transport physics and providing novel degrees of freedom in the spintronic applications of emerging topological magnets., Comment: 17 pages, 4 figs

Published
2021

7. Large barocaloric effect with high pressure-driving efficiency in hexagonal MnNi0.77Fe0.23Ge alloy

Author

Zeng, Qingqi, Shen, Jianlei, Liu, Enke, Xi, Xuekui, Wang, Wenhong, Wu, Guangheng, and Zhang, Xixiang

Subjects
Condensed Matter - Materials Science
Abstract

The hydrostatic pressure is expected to be an effective knob to tune the magnetostructural phase transitions of hexagonal MMX alloy. In this study, magnetization measurements under hydrostatic pressure were performed on a MMX martensitic MnNi0.77Fe0.23Ge alloy. The magnetostructural transition temperature can be efficiently tuned to lower temperatures by applying moderate pressures, with a giant shift rate of -151 K GPa-1. A temperature span of 30 K is obtained under the pressure, within which a large magnetic entropy change of -23 J kg-1 K-1 in a field change of 5 T is induced by the mechanical energy gain due to the large volume change. Meanwhile, a decoupling of structural and magnetic transitions is observed at low temperatures when the martensitic transition temperature is lower than the Curie temperature. These results show a multi-parameter tunable caloric effect that benefits the solid-state cooling., Comment: 8 pages, 4 figs

Published
2021
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8. Planar topological Hall effect in a hexagonal ferromagnetic Fe5Sn3 single crystal

Author

Li, Hang, Ding, Bei, Chen, Jie, Li, Zefang, Xi, Xuekui, Wu, Guangheng, and Wang, Wenhong

Subjects
Condensed Matter - Materials Science
Abstract

The planar topological Hall effect (PTHE), appeared when the magnetic field tended to be along the current, is believed to result from the real-space Berry curvature of the spin spiral structure and has been experimentally observed in skyrmion-hosting materials. In this paper, we report an experimental observation of the PTHE in a hexagonal ferromagnetic Fe5Sn3 single crystal. With a current along the c axis of Fe5Sn3, the transverse resistivity curves exhibited obvious peaks near the saturation field as the magnetic field rotated to the current and appeared more obvious with increasing temperature, which was related to the noncoplanar spin structure in Fe5Sn3. This spin structure induced nonzero scalar spin chirality, which acted as fictitious magnetic fields to conduction electrons and contributed the additional transverse signal. These findings deepen the understanding of the interaction between conduction electrons and complex magnetic structures and are instructive for the design of next-generation spintronic devices.

Published
2021
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9. Abnormal Critical Fluctuations Revealed by Magnetic Resonance in the Two-Dimensional Ferromagnetic Insulators

Author

Li, Zefang, Xu, Dong-Hong, Li, Xue, Liao, Hai-Jun, Xi, Xuekui, Yu, Yi-Cong, and Wang, Wenhong

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

Phase transitions and critical phenomena, which are dominated by fluctuations and correlations, are one of the fields replete with physical paradigms and unexpected discoveries. Especially for two-dimensional magnetism, the limitation of the Ginzburg criterion leads to enhanced fluctuations breaking down the mean-field theory near a critical point. Here, by means of magnetic resonance, we investigate the behavior of critical fluctuations in the two-dimensional ferromagnetic insulators $\rm CrXTe_3 (X=Si, Ge)$. After deriving the classical and quantum models of magnetic resonance, we deem the dramatic anisotropic shift of the measured $g$ factor to originate from fluctuations with anisotropic interactions. The deduction of the $g$ factor behind the fluctuations is consistent with the spin-only state (${g\approx}$ 2.050(10) for $\rm CrSiTe_3$ and 2.039(10) for $\rm CrGeTe_3$). Furthermore, the abnormal enhancement of $g$ shift, supplemented by specific heat and magnetometry measurements, suggests that $\rm CrSiTe_3$ exhibits a more typical two-dimensional nature than $\rm CrGeTe_3$ and may be closer to the quantum critical point.

Published
2021

10. 33% Giant Anomalous Hall Current Driven by both Intrinsic and Extrinsic Contributions in Magnetic Weyl Semimetal Co3Sn2S2

Author

Shen, Jianlei, Zeng, Qingqi, Zhang, Shen, Sun, Hongyi, Yao, Qiushi, Xi, Xuekui, Wang, Wenhong, Wu, Guangheng, Shen, Baogen, Liu, Qihang, and Liu, Enke

Subjects
Condensed Matter - Materials Science
Abstract

Anomalous Hall effect (AHE) can be induced by intrinsic mechanism due to the band Berry phase and extrinsic one arising from the impurity scattering. The recently discovered magnetic Weyl semimetal Co3Sn2S2 exhibits a large intrinsic anomalous Hall conductivity (AHC) and a giant anomalous Hall angle (AHA). The predicted energy dependence of the AHC in this material exhibits a plateau at 1000 {\Omega}-1 cm-1 and an energy width of 100 meV just below EF, thereby implying that the large intrinsic AHC will not significantly change against small-scale energy disturbances such as slight p-doping. Here, we successfully trigger the extrinsic contribution from alien-atom scattering in addition to the intrinsic one of the pristine material by introducing a small amount of Fe dopant to substitute Co in Co3Sn2S2. Our experimental results show that the AHC and AHA can be prominently enhanced up to 1850 {\Omega}-1 cm-1 and 33%, respectively, owing to the synergistic contributions from the intrinsic and extrinsic mechanisms as distinguished by the TYJ model. In particular, the tuned AHA holds a record value in low fields among known magnetic materials. This study opens up a pathway to engineer giant AHE in magnetic Weyl semimetals, thereby potentially advancing the topological spintronics/Weyltronics., Comment: 16 pages, 5 figs

Published
2020
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11. Large anisotropic topological Hall effect in a hexagonal non-collinear magnet Fe5Sn3

Author

Li, Hang, Ding, Bei, Chen, Jie, Li, Zefang, Liu, Enke, Xi, Xuekui, Wu, Guangheng, and wang, Wenhong

Subjects
Condensed Matter - Materials Science
Abstract

We report the observation of a large anisotropic topological Hall effect (THE) in the hexagonal non-collinear magnet Fe5Sn3 single crystals. It is found that the sign of the topological Hall resistivity is negative when a magnetic field H perpendicular to the bc-plane (H\perp bc-plane), however, it changes form negative to positive when H parallel to the c-axis (H\parallel c-axis). The value of topological Hall resistivity increased with the increasing temperature and reached approximately -2.12 \mu\Omega cm (H\perp bc-plane) and 0.5 \mu\Omega cm (H\parallel c-axis) at 350 K, respectively. Quantitative analyses of the measured data suggest that the observed anisotropic THE may originate from the opposite scalar spin chirality induced by the magnetic fields perpendicular and parallel to the c-axis, respectively., Comment: 20 pages, 11 figures

Published
2020
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12. Large anomalous Hall effect in a hexagonal ferromagnetic Fe5Sn3 single crystal

Author

Li, Hang, Zhang, Bingwen, Liang, Jinghua, Ding, Bei, Chen, Jie, Shen, Jianlei, Li, Zefang, Liu, Enke, Xi, Xuekui, Wu, Guangheng, Yao, Yuan, Yang, Hongxin, and Wang, Wenhong

Subjects
Condensed Matter - Materials Science
Abstract

In this paper, we report an experimental observation of the large anomalous Hall effect (AHE) in a hexagonal ferromagnetic Fe5Sn3 single crystal with current along the b axis and a magnetic field normal to the bc plane. The intrinsic contribution of the anomalous Hall conductance sigma_AH^int was approximately 613 {\Omega}-1 cm-1, which was more than 3 times the maximum value in the frustrated kagome magnet Fe3Sn2 and nearly independent of the temperature over a wide range between 5 and 350 K. The analysis results revealed that the large AHE was dominated by a common, intrinsic term, while the extrinsic contribution, i.e., the skew scattering and side jump, turned out to be small. In addition to the large AHE, it was found the types of majority carriers changed at approximately 275 and 30 K, consistent with the critical temperatures of the spin reorientation. These findings suggest that the hexagonal ferromagnetic Fe5Sn3 single crystal is an excellent candidate to use for the study of the topological features in ferromagnets., Comment: accepted as a rapid communication in Phy. Rev. B

Published
2020
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13. Disorder-Induced Elevation of Intrinsic Anomalous Hall Conductance in an Electron-Doped Magnetic Weyl Semimetal

Author

Shen, Jianlei, Yao, Qiushi, Zeng, Qingqi, Sun, Hongyi, Xi, Xuekui, Wu, Guangheng, Wang, Wenhong, Liu, Qihang, and Liu, Enke

Subjects
Condensed Matter - Materials Science
Abstract

Topological materials are expected to show distinct transport signatures due to their unique band-inversion character and band-crossing points. However, the intentional modulation of such topological responses by experimentally feasible means is less explored. Here, an unusual elevation of anomalous Hall effect (AHE) is obtained in electron(Ni)-doped magnetic Weyl semimetal Co3-xNixSn2S2, showing peak values of anomalous Hall-conductivity, Hall-angle and Hall-factor at a relatively low doping level of x = 0.11. The separation of intrinsic and extrinsic contributions to total AHE using TYJ scaling model indicates that such significant enhancement is dominated by the intrinsic mechanism of electronic Berry curvature. Theoretical calculations reveal that compared with the Fermi-level shifting from electron filling, a usually overlooked effect of doping, i.e., local disorder, imposes a striking effect on broadening the bands and narrowing the inverted gap, and thus results in an elevation of the integrated Berry curvature. Our results not only realize the enhancement of AHE in a magnetic Weyl semimetal, but also provide a practical design principle to modulate the bands and transport properties in topological materials, by exploiting the disorder effect of doping.

Published
2020
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14. Observation of Magnetic Skyrmion Bubbles in a van der Waals ferromagnet Fe3GeTe2

Author

Ding, Bei, Li, Zefang, Xu, Guizhou, Li, Hang, Hou, Zhipeng, Liu, Enke, Xi, Xuekui, Xu, Feng, Yao, Yuan, and Wang, Wenhong

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Two-dimensional (2D) van der Waals (vdW) magnetic materials have recently been introduced as a new horizon in materials science and enable the potential applications for next-generation spintronic devices. Here, in this communication, the observations of stable Bloch-type magnetic skyrmions in single crystals of 2D vdW Fe3GeTe2 (FGT) are reported by using in-situ Lorentz transmission electron microscopy (TEM). We find the ground-state magnetic stripe domains in FGT transform into skyrmion bubbles when an external magnetic field is applied perpendicularly to the (001) thin plate with temperatures below the Curie-temperature TC. Most interestingly, a hexagonal lattice of skyrmion bubbles is obtained via field cooling manipulation with magnetic field applied along the [001] direction. Owing to their topological stability, the skyrmion bubble lattices are stable to large field-cooling tilted angles and further reproduced by utilizing the micromagnetic simulations. These observations directly demonstrate that the 2D vdW FGT possesses a rich variety of topological spin textures, being of a great promise candidate for future applications in the field of spintronics., Comment: 17 pages,5 figures. Accepted by Nano Letters

Published
2019
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15. Large topological Hall effect in a geometrically frustrated kagome magnet Fe$_3$Sn$_2$

Author

Li, Hang, Ding, Bei, Chen, Jie, Li, Zefang, Hou, Zhipeng, Liu, Enke, Zhang, Hongwei, Xi, Xuekui, Wu, Guangheng, and Wang, Wenhong

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

We report on the observation of a large topological Hall effect (THE) over a wide temperature region in a geometrically frustrated Fe3Sn2 magnet with a kagome-bilayer structure. We found that the magnitude of the THE resistivity increases with temperature and reaches -0.875 {\mu}{\Omega}.cm at 380 K. Moreover, the critical magnetic fields with the change of THE are consistent with the magnetic structure transformation, which indicates that the real-space fictitious magnetic field is proportional to the formation of magnetic skyrmions in Fe3Sn2. The results strongly suggest that the large THE originates from the topological magnetic spin textures and may open up further research opportunities in exploring emergent phenomena in kagome materials., Comment: 18 pages, 4 figures and Supplementary materials

Published
2019
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17. In-plane anisotropic magnetoresistance and planar Hall effect in off-stoichiometric single crystal Mn3Ga.

Author

Song, Linxuan, Zhou, Feng, Chen, Jie, Li, Hang, Xi, Xuekui, Lau, Yong-Chang, and Wang, Wenhong

Subjects
ENHANCED magnetoresistance, HALL effect, WEYL fermions, SINGLE crystals, MAGNETIC anisotropy
Abstract

We report the observation of in-plane anisotropic magnetoresistance (AMR) and planar Hall effect in our recently discovered kagome antiferromagnetic off-stoichiometric single crystal of Mn3Ga. We found that the in-plane AMR is dominated by a sixfold symmetry at low temperature due to the kagome lattice magnetocrystalline anisotropy. However, an unusual fourfold symmetry is also revealed by the angular-dependent AMR measurements, which originates from the little distortion of the crystal accompanying the slight ferromagnetic transition. Moreover, we also found a clear planar Hall effect signal in off-stoichiometric single crystal of Mn3Ga, which may be related to the chiral anomaly, one of the signatures of the magnetic Weyl fermions. [ABSTRACT FROM AUTHOR]

Published
2024
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20. NMR Evidence for the Topologically Nontrivial Nature in a Family of Half-Heusler Compounds

Author

Zhang, Xiaoming, Hou, Zhipeng, Wang, Yue, Xu, Guizhou, Shi, Chenglong, Liu, EnKe, Xi, Xuekui, Wang, Wenhong, Wu, Guangheng, and Zhang, Xi-xiang

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

Spin-orbit coupling (SOC) is expected to partly determine the topologically nontrivial electronic structure of heavy half-Heusler ternary compounds. However, to date, attempts to experimentally observe either the strength of SOC or how it modifies the bulk band structure have been unsuccessful. By using bulk-sensitive nuclear magnetic resonance (NMR) spectroscopy combined with first-principles calculations, we reveal that 209Bi NMR isotropic shifts scale with relativity in terms of the strength of SOC and average atomic numbers, indicating strong relativistic effects on NMR parameters. According to first-principles calculations, we further claim that nuclear magnetic shieldings from relativistic p1/2 states and paramagnetic contributions from low-lying unoccupied p3/2 states are both sensitive to the details of band structures tuned by relativity, which explains why the hidden relativistic effects on band structure can be revealed by 209Bi NMR isotropic shifts in topologically nontrivial half-Heusler compounds. Used in complement to surface-sensitive methods, such as angle resolved photon electron spectroscopy and scanning tunneling spectroscopy, NMR can provide valuable information on bulk electronic states., Comment: accepted for publication in Scientific Reports (2016)

Published
2015

21. High Electron Mobility and Large Magnetoresistance in the Half-Heusler Semimetal LuPtBi

Author

Hou, Zhipeng, Wang, Wenhong, Xu, Guizhou, Zhang, Xiaoming, Wei, Zhiyang, Shen, Shipeng, Liu, Enke, Yao, Yuan, Chai, Yisheng, Sun, Young, Xi, Xuekui, Wang, Wenquan, Liu, Zhongyuan, Wu, Guangheng, and Zhang, Xi-xiang

Subjects
Condensed Matter - Materials Science
Abstract

Materials with high carrier mobility showing large magnetoresistance (MR) have recently received much attention because of potential applications in future high-performance magneto-electric devices. Here, we report on the discovery of an electron-hole-compensated half-Heusler semimetal LuPtBi that exhibits an extremely high electron mobility of up to 79000 cm2/Vs with a non-saturating positive MR as large as 3200% at 2 K. Remarkably, the mobility at 300 K is found to exceed 10500 cm2/Vs, which is among the highest values reported in three-dimensional bulk materials thus far. The clean Shubnikov-de Haas quantum oscillation observed at low temperatures and the first-principles calculations together indicate that the high electron mobility is due to a rather small effective carrier mass caused by the distinctive band structure of the crystal. Our finding provide a new approach for finding large, high-mobility MR materials by designing an appropriate Fermi surface topology starting from simple electron-hole-compensated semimetals., Comment: 26 pages,10 pages, 1 SUPPLEMENTARY, accepted for publication in Physical review B

Published
2015
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22. Transition from semiconducting to metallic-like conducting and weak antilocalization effect in single crystals of LuPtSb

Author

Hou, Zhipeng, Wang, Yue, Xu, Guizhou, Zhang, Xiaoming, Liu, Enke, Wang, Wenquan, Liu, Zhongyuan, Xi, Xuekui, Wang, Wenhong, and Wu, Guangheng

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

High quality half-Heusler single crystals of LuPtSb have been synthesized by a Pb flux method. The temperature dependent resistivity and Hall effects indicate that the LuPtSb crystal is a p-type gapless semiconductor showing a transition from semiconducting to metallic conducting at 150 K. Moreover, a weakly temperature-dependent positive magnetoresistance (MR) as large as 109 % and high carrier mobility up to 2950 cm2/Vs are experimentally observed at temperatures below 150 K. The low-field MR data shows evidence for weak antilocalization (WAL) effect at temperatures even up to 150 K. Analysis of the temperature and angle dependent magnetoconductance manifests that the WAL effect originates from the bulk contribution owing to the strong spin-orbital coupling., Comment: 13 pages, 4 figs, submitted

Published
2015
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23. A Giant Magneto‐Superelasticity of 5% Enabled by Introducing Ordered Dislocations in Ni34Co8Cu8Mn36Ga14 Single Crystal.

Author

Yu, Qijia, Wang, Jingmin, Liang, Chuanxin, Meng, Jiaxi, Xu, Jinyue, Liu, Yang, Zhao, Shiteng, Xi, Xuekui, Xi, Chuanying, Yang, Ming, Si, Chen, He, Yangkun, Wang, Dong, and Jiang, Chengbao

Subjects
SINGLE crystals, SHAPE memory alloys, MARTENSITIC transformations, MANGANESE alloys, TWIN boundaries, MAGNETIC fields
Abstract

Elasticity, featured by a recoverable strain, refers to the ability that materials can return to their original shapes after deformation. Typically, the elastic strains of most metals are well‐known 0.2%. In shape memory alloys and high entropy alloys, the elastic strains can be several percent, as called superelasticity, which are all triggered by external stresses. A superelasticity induced by magnetic field, termed as magneto‐superelasticity, is extremely important for contactless work of materials and for developing brand‐new large stroke actuators and high efficiency energy transducers. In magnetic shape memory alloys, the twin boundary motion driven by magnetic field can output a strain of several percent. However, this strain is unrecoverable when removing the magnetic field and hence it is not magneto‐superelasticity. Here, a giant magneto‐superelasticity of 5% in a Ni34Co8Cu8Mn36Ga14 single crystal is reported by introducing arrays of ordered dislocations to form preferentially oriented martensitic variants during the magnetically induced reverse martensitic transformation. This work provides an opportunity to achieve high performance in functional materials by defect engineering. [ABSTRACT FROM AUTHOR]

Published
2024
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27. NMR evidence for enhanced orbital diamagnetism in topologically nontrivial half-Heusler semimetals

Author

Shi, Chenglong, Xi, Xuekui, Hou, Zhipeng, Zhang, Xiaoming, Xu, Guizhou, Liu, Enke, Wang, Wenquan, Wang, Wenhong, and Wu, Guangheng

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

209Bi nuclear magnetic resonance (NMR) spectroscopy was employed to probe potential spin-orbit effects on orbital diamagnetism in YPtBi and YPdBi crystals. The observed opposite sign and temperature dependent magnitude of 209Bi NMR shifts of both crystals reveal experimental signatures of enhanced orbital diamagnetism induced by spin-orbit interactions. This investigation indicates that NMR isotropic shifts might be beneficial in search of interesting spin-electronic phases among a vast number of topological nontrivial half-Heusler semimetals., Comment: 14 pages, 3 figs., and one table. Submitted for publication

Published
2014
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32. Tuning the structural, magnetic, and transport properties of Mn3Ga alloys.

Author

Song, Linxuan, Li, Weike, Lv, Senhao, Xi, Xuekui, Zhao, Dongliang, He, Jun, and Wang, Wenhong

Abstract

Mn3Ga alloys with different crystal modifications, including a disordered L12-type cubic structure, a D022-tetragonal structure, and a D019-hexagonal structure showing two isomorphic heteromagnetic phases, ε-phase and η-phase, were investigated systematically. We found that the disordered cubic phase and the hexagonal ε-phase can be synthesized with Mn compositions ranging from 70 to 75 at. % by rapid melt-spinning. Moreover, the disordered cubic phase could transform to the tetragonal phase after being subjected to low-temperature postannealing. Most importantly, we found that proper postannealing conditions can enable these different crystal modification phases to transform to the hexagonal η-phase. As a result, the two isomorphic heteromagnetic hexagonal phases are clearly distinguished, and their interesting magnetic and transport properties are discussed. [ABSTRACT FROM AUTHOR]

Published
2022
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36. NMR study of charge density wave phase in the kagome metal RbV3Sb5.

Author

Zhang, Xin, Li, Yongkai, Zheng, Jiaxin, Zhou, Feng, Wu, Quansheng, Xi, Xuekui, Lau, Yongchang, Wang, Zhiwei, and Wang, Wenhong

Subjects
CHARGE density waves, NUCLEAR magnetic resonance spectroscopy, ATOMIC structure, FERMI surfaces, NUCLEAR magnetic resonance, PHASE transitions
Abstract

The mechanism of charge-density-wave (CDW) phase in one-dimensional lattices can be well described in theory. Whether similar mechanism works in two-dimensional systems is still a mystery. In this work, we employed 51V solid-state nuclear magnetic resonance (NMR) spectroscopy combined with first-principles computations to probe atomic structure and electronic properties at V sites in a quasi-two-dimensional crystal RbV3Sb5. Clear evidence of the CDW phase transition was observed from the temperature-dependent 51V NMR measurements. The sharp transition of 51V Knight shifts and electric field gradients (EFG) across the CDW transition supports the view that energy gap is formed by the nesting of partial Fermi surface in accompany with the superlattice formation. The calculated EFG parameters were also compared with our experiments, and the results suggest that the charge modulation of the CDW order is inverse Star-of-David pattern. [ABSTRACT FROM AUTHOR]

Published
2024
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37. Microwave Hydrothermal Preparation of VO2.

Author

Lu, Di, Li, Dehu, Wang, Yue, Zhang, Yuxin, Yu, Zhisong, and Xi, Xuekui

Subjects
PHASE transitions, TRANSITION temperature, SCANNING electron microscopes, OXYGEN consumption, VANADIUM dioxide
Abstract

As a thermal phase transition material, VO2 is famous for its phase transition performance. When the temperature is lower than the phase transition temperature, VO2 behaves as a semiconductor with high infrared transmittance. When the temperature exceeds the phase transition temperature, VO2 exhibits a metallic state and has a high refractive index for infrared. Regulation of phase transition temperature is key to the application of VO2. In this article, microwave hydrothermal is used to prepare VO2. H+ concentration, microwave power, annealing temperature, and annealing time are used as variable conditions to find the best preparation conditions. The preparation of samples is studied by X‐ray diffractometer, scanning electron microscope, and differential scanning calorimeter. After comparative research, the optimum preparation process of vanadium dioxide by microwave hydrothermal method is found. In addition, by varying the acidic conditions and microwave power during the preparation process, the phase transition temperature of VO2 can be regulated. [ABSTRACT FROM AUTHOR]

Published
2024
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43. Asymmetric magnetic-field-induced phase transformation in Fe48Mn24Ga28 Heusler alloy.

Author

Li, Weike, Zhang, Yajiu, Song, Linxuan, Xi, Xuekui, Lau, Yong-Chang, Wang, Wenhong, and Wu, Guangheng

Subjects
PHASE transitions, HEUSLER alloys, IRON-manganese alloys, CURIE temperature, MARTENSITIC transformations, MAGNETIC fields, MAGNETIC entropy
Abstract

We report on the conceptual design and experimental realization of a ternary Heusler-based ferromagnetic martensitic phase transformation alloy Fe48Mn24Ga28 that exhibits asymmetric magnetostructural coupling between the forward austenite-to-martensite and the reverse martensite-to-austenite phase transformations. By tuning the Curie temperature of the high-temperature austenite to be within the thermal hysteresis of the first-order phase transformation, dissimilar change in magnetization can be associated with the forward and reverse phase transformations, respectively. We show that such an asymmetry leads to enlargement of the thermal hysteresis with an applied external magnetic field. Furthermore, partly due to the field-enhanced thermal hysteresis, the magnetic-field-induced martensitic phase transformation is irreversible in such a system. This work suggests the intricate correlation between magnetostructural coupling, thermal hysteresis, and magnetic-field-induced phase transformation, which can be exploited for designing magnetic phase transformation alloys that show extended functionalities. [ABSTRACT FROM AUTHOR]

Published
2023
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48. Plateau-like magnetoresistance and topological Hall effect in Kagome magnets TbCo2 and DyCo2.

Author

Huang, Dan, Li, Hang, Ding, Bei, Xi, Xuekui, Gao, Jianrong, Lau, Yong-Chang, and Wang, Wenhong

Subjects
HALL effect, MAGNETORESISTANCE, MAGNETIC fields, GIANT magnetoresistance, TRANSPORT theory, TERBIUM
Abstract

Magnetoresistance (MR) and Hall resistivity of TbCo2 and DyCo2 with a Co Kagome lattice were investigated. Apart from giant negative magnetoresistance (MR) at TC, plateau-like MR and a topological Hall effect (THE) are observed at a low magnetic field for each compound below respective TC. The plateau-like MR is attributed to a compensation of negative MR with a ferromagnetically ordered structure of Tb atoms by positive MR with a noncoplanar spin structure of the Co Kagome lattice. The THE is attributed to the noncoplanar spin structure of the Co Kagome lattice only. The MR and the Hall resistivity of each compound are reduced dramatically and undergo a reversal of its sign during cooling. The reversal phenomenon at the low temperature can be related to the freezing of spins of Co atoms. The transport in DyCo2 is more sensitive to magnetic fields than that in TbCo2 which is consistent with a stronger 4f–3d interaction. Observations of these transport phenomena make RCo2 compounds promising for functional applications in spintronic devices. [ABSTRACT FROM AUTHOR]

Published
2022
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