Your search keyword '"Wang, Jia-Ou"' showing total 11 results

1. Unusual charge density wave introduced by Janus structure in monolayer vanadium dichalcogenides

Author

Xu, Ziqiang, Shao, Yan, Huang, Chun, Hu, Genyu, Hu, Shihao, Li, Zhi-Lin, Hao, Xiaoyu, Hou, Yanhui, Zhang, Teng, Shi, Jin-An, Liu, Chen, Wang, Jia-Ou, Zhou, Wu, Zhou, Jiadong, Ji, Wei, Qiao, Jingsi, Wu, Xu, Gao, Hong-Jun, and Wang, Yeliang

Subjects

Condensed Matter - Materials Science, Quantum Physics

Abstract

As a fundamental structural feature, the symmetry of materials determines the exotic quantum properties in transition metal dichalcogenides (TMDs) with charge density wave (CDW). Breaking the inversion symmetry, the Janus structure, an artificially constructed lattice, provides an opportunity to tune the CDW states and the related properties. However, limited by the difficulties in atomic-level fabrication and material stability, the experimental visualization of the CDW states in 2D TMDs with Janus structure is still rare. Here, using surface selenization of VTe2, we fabricated monolayer Janus VTeSe. With scanning tunneling microscopy, an unusual root13-root13 CDW state with threefold rotational symmetry breaking was observed and characterized. Combined with theoretical calculations, we find this CDW state can be attributed to the charge modulation in the Janus VTeSe, beyond the conventional electron-phonon coupling. Our findings provide a promising platform for studying the CDW states and artificially tuning the electronic properties toward the applications.

Published

2024

2. Strain mediated phase crossover in Ruddlesden Popper nickelates

Author

Cui, Ting, Choi, Songhee, Lin, Ting, Liu, Chen, Wang, Gang, Wang, Ningning, Chen, Shengru, Hong, Haitao, Rong, Dongke, Wang, Qianying, Jin, Qiao, Wang, Jia-Ou, Gu, Lin, Ge, Chen, Wang, Can, Cheng, Jin Guang, Zhang, Qinghua, Si, Liang, Jin, Kui-juan, and Guo, Er-Jia

Subjects

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

Abstract

Recent progress on the signatures of pressure-induced high temperature superconductivity in Ruddlesden Popper (RP) nickelates (Lan+1NinO3n+1) has attracted growing interest in both theoretical calculations and experimental efforts. The fabrication of high-quality single crystalline RP nickelate thin films is critical for possible reducing the superconducting transition pressure and advancing applications in microelectronics in the future. In this study, we report the observations of an active phase transition in RP nickelate films induced by misfit strain. We found that RP nickelate films favor the perovskite structure (n = infinite) under tensile strains, while compressive strains stabilize the La3Ni2O7 (n = 2) phase. The selection of distinct phases is governed by the strain dependent formation energy and electronic configuration. In compressively strained La3Ni2O7, we experimentally determined splitting energy is ~0.2 eV and electrons prefer to occupy in-plane orbitals. First principles calculations unveil a robust coupling between strain effects and the valence state of Ni ions in RP nickelates, suggesting a dual driving force for the inevitable phase co-existence transition in RP nickelates. Our work underscores the sensitivity of RP nickelate formation to epitaxial strain, presenting a significant challenge in fabricating pure-phase RP nickelate films. Therefore, special attention to stacking defects and grain boundaries between different RP phases is essential when discussing the pressure-induced superconductivity in RP nickelates., Comment: 29 pages, 5 figures, one supplementary materials

Published

2023

3. Syntropic spin alignment at the interface between ferromagnetic and superconducting nitrides

Author

Jin, Qiao, Zhang, Qinghua, He, Bai, Zou, Yuting, Ga, Yonglong, Chen, Shengru, Hong, Haitao, Cui, Ting, Rong, Dongke, Wang, Jia-Ou, Wang, Can, Cao, Yanwei, Gu, Lin, Wang, Shanmin, Jiang, Kun, Cheng, Zhi-Gang, Zhu, Tao, Yang, Hongxin, Jin, Kui-juan, and Guo, Er-Jia

Subjects

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

Abstract

The magnetic correlations at the superconductor/ferromagnet (S/F) interfaces play a crucial role in realizing dissipation-less spin-based logic and memory technologies, such as triplet-supercurrent spin-valves and "{\pi}" Josephson junctions. Here we report the coexistence of an induced large magnetic moment and a crypto ferromagnetic state at high-quality nitride S/F interfaces. Using polarized neutron reflectometry and d. c. SQUID measurements, we quantitatively determined the magnetization profile of S/F bilayer and confirmed the induced magnetic moment in the adjacent superconductor only exists below TC. Interestingly, the direction of the induced moment in the superconductors was unexpectedly parallel to that in the ferromagnet, which contrasts with earlier findings in S/F heterostructures based on metals or oxides. The first-principles calculations verify the observed unusual interfacial spin texture is caused by the Heisenberg direct exchange coupling through d orbital overlapping and severe charge transfer across the interfaces. Our work establishes an incisive experimental probe for understanding the magnetic proximity behavior at S/F interfaces and provides a prototype epitaxial building block for superconducting spintronics., Comment: 21 pages, 5 figures, supplementary file with 14 figures

Published

2023

4. Miniature Magnetic Nano islands in a Morphotropic Cobaltite Matrix

Author

Chen, Shengru, Rong, Dongke, Xu, Yue, Cai, Miming, Li, Xinyan, Zhang, Qinghua, Xu, Shuai, Shang, Yan-Xing, Hong, Haitao, Cui, Ting, Jin, Qiao, Wang, Jia-Ou, Guo, Haizhong, Gu, Lin, Zheng, Qiang, Wang, Can, Zhang, Jinxing, Liu, Gang-Qin, Jin, Kui-juan, and Guo, Er-Jia

Subjects

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

Abstract

High-density magnetic memories are key components in spintronics, quantum computing, and energy-efficient electronics. Reduced dimensionality and magnetic domain stability at the nanoscale are essential for the miniaturization of magnetic storage units. Yet, inducing magnetic order, and selectively tuning spin-orbital coupling at specific locations have remained challenging. Here we demonstrate the construction of switchable magnetic nano-islands in a nonmagnetic matrix based on cobaltite homo-structures. The magnetic and electronic states are laterally modified by epitaxial strain, which is regionally controlled by freestanding membranes. Atomically sharp grain boundaries isolate the crosstalk between magnetically distinct regions. The minimal size of magnetic nano-islands reaches 35 nm in diameter, enabling an areal density of 400 Gbit per inch square. Besides providing an ideal platform for precisely controlled read and write schemes, this methodology can enable scalable and patterned memories on silicon and flexible substrates for various applications., Comment: 20 pages,4 figures

Published

2023

5. Room-temperature ferromagnetism at an oxide/nitride interface

Author

Jin, Qiao, Wang, Zhiwen, Zhang, Qinghua, Yu, Yonghong, Lin, Shan, Chen, Shengru, Qi, Mingqun, Bai, He, Li, Qian, Wang, Le, Yin, Xinmao, Tang, Chi Sin, Wee, Andrew T. S., Meng, Fanqi, Zhao, Jiali, Wang, Jia-Ou, Guo, Haizhong, Ge, Chen, Wang, Can, Yan, Wensheng, Zhu, Tao, Gu, Lin, Chambers, Scott A., Das, Sujit, Liu, Gang-Qin, Wang, Shanmin, Jin, Kui-juan, Yang, Hongxin, and Guo, Er-Jia

Subjects

Condensed Matter - Materials Science

Abstract

Heterointerfaces have led to the discovery of novel electronic and magnetic states because of their strongly entangled electronic degrees of freedom. Single-phase chromium compounds always exhibit antiferromagnetism following the prediction of Goodenough-Kanamori rules. So far, exchange coupling between chromium ions via hetero-anions has not been explored and the associated quantum states is unknown. Here we report the successful epitaxial synthesis and characterizations of chromium oxide (Cr2O3)-chromium nitride (CrN) superlattices. Room-temperature ferromagnetic spin ordering is achieved at the interfaces between these two antiferromagnets, and the magnitude of the effect decays with increasing layer thickness. First-principles calculations indicate that robust ferromagnetic spin interaction between Cr3+ ions via anion-hybridizations across the interface yields the lowest total energy. This work opens the door to fundamental understanding of the unexpected and exceptional properties of oxide-nitride interfaces and provides access to hidden phases at low-dimensional quantum heterostructures., Comment: 21 pages, 4 figures

Published

2021

6. Anisotropic electronic phase transition in CrN epitaxial thin films

Author

Jin, Qiao, Zhao, Jiali, Roldan, Manuel, Lin, Shan, Chen, Shengru, Hong, Haitao, Fan, Yiyan, Rong, Dongke, Guo, Haizhong, Ge, Chen, Wang, Can, Wang, Jia-Ou, Wang, Shanmin, Jin, Kui-juan, and Guo, Er-Jia

Subjects

Condensed Matter - Materials Science

Abstract

Electronic phase transition in strongly correlated materials is extremely sensitive to the dimensionality and crystallographic orientations. Transition metal nitrides (TMNs) are seldom investigated due to the difficulty in fabricating the high-quality and stoichiometric single crystals. In this letter, we report the epitaxial growth and electronic properties of CrN films on different-oriented NdGaO3 (NGO) substrates. Astonishingly, the CrN films grown on (110)-oriented NGO substrates maintain a metallic phase, whereas the CrN films grown on (010)-oriented NGO substrates are semiconducting. We attribute the unconventional electronic transition in the CrN films to the strongly correlation with epitaxial strain. The effective modulation of bandgap by the anisotropic strain triggers the metal-to-insulator transition consequently. This work provides a convenient approach to modify the electronic ground states of functional materials using anisotropic strain and further stimulates the investigations of TMNs.

Published

2021

7. Structural Twinning-induced Insulating Phase in CrN (111) Films

Author

Jin, Qiao, Wang, Zhiwen, Zhang, Qinghua, Zhao, Jiali, Cheng, Hu, Lin, Shan, Chen, Shengru, Chen, Shuang, Guo, Haizhong, He, Meng, Ge, Chen, Wang, Can, Wang, Jia-Ou, Gu, Lin, Wang, Shanmin, Yang, Hongxin, Jin, Kui-juan, and Guo, Er-Jia

Subjects

Condensed Matter - Materials Science

Abstract

Electronic states of a correlated material can be effectively modified by structural variations delivered from a single-crystal substrate. In this letter, we show that the CrN films grown on MgO (001) substrates have a (001) orientation, whereas the CrN films on {\alpha}-Al2O3 (0001) substrates are oriented along (111) direction parallel to the surface normal. Transport properties of CrN films are remarkably different depending on crystallographic orientations. The critical thickness for the metal-insulator transition (MIT) in CrN 111 films is significantly larger than that of CrN 001 films. In contrast to CrN 001 films without apparent defects, scanning transmission electron microscopy results reveal that CrN 111 films exhibit strain-induced structural defects, e. g. the periodic horizontal twinning domains, resulting in an increased electron scattering facilitating an insulating state. Understanding the key parameters that determine the electronic properties of ultrathin conductive layers is highly desirable for future technological applications., Comment: 19 pages, 4 figures

Published

2021

8. Dimensional Control of Octahedral Tilt in SrRuO3 via Infinite-layered Oxides

Author

Lin, Shan, Zhang, Qinghua, Sang, Xiahan, Zhao, Jiali, Cheng, Sheng, Huon, Amanda, Jin, Qiao, Chen, Shuang, Chen, Shengru, Guo, Haizhong, He, Meng, Ge, Chen, Wang, Can, Wang, Jia-Ou, Fitzsimmons, Michael R., Gu, Lin, Zhu, Tao, Jin, Kui-juan, and Guo, Er-Jia

Subjects

Condensed Matter - Materials Science

Abstract

Manipulation of octahedral distortion at atomic length scale is an effective means to tune the physical ground states of functional oxides. Previous work demonstrates that epitaxial strain and film thickness are variable parameters to modify the octahedral rotation and tilt. However, selective control of bonding geometry by structural propagation from adjacent layers is rarely studied. Here we propose a new route to tune the ferromagnetic response in SrRuO3 (SRO) ultrathin layers by oxygen coordination of adjacent SrCuO2 (SCO) layers. The infinite-layered CuO2 in SCO exhibits a structural transformation from "planar-type" to "chain-type" as reducing film thickness. These two orientations dramatically modify the polyhedral connectivity at the interface, thus altering the octahedral distortion of SRO. The local structural variation changes the spin state of Ru and hybridization strength between Ru 4d and O 2p orbitals, leading to a significant change in the magnetoresistance and anomalous Hall resistivity of SRO layers. These findings could launch further investigations into adaptive control of magnetoelectric properties in quantum oxide heterostructures using oxygen coordination.

Published

2021

9. Strong Ferromagnetism Achieved via Breathing Lattices in Atomically Thin Cobaltites

Author

Li, Sisi, Zhang, Qinghua, Lin, Shan, Sang, Xiahan, Need, Ryan F., Roldan, Manuel A., Cui, Wenjun, Hu, Zhiyi, Jin, Qiao, Chen, Shuang, Zhao, Jiali, Wang, Jia-Ou, Wang, Jiesu, He, Meng, Ge, Chen, Wang, Can, Lu, Hui-Bin, Wu, Zhenping, Guo, Haizhong, Tong, Xin, Zhu, Tao, Kirby, Brian, Gu, Lin, Jin, Kui-juan, and Guo, Er-Jia

Subjects

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

Abstract

Low-dimensional quantum materials that remain strongly ferromagnetic down to mono layer thickness are highly desired for spintronic applications. Although oxide materials are important candidates for next generation of spintronic, ferromagnetism decays severely when the thickness is scaled to the nano meter regime, leading to deterioration of device performance. Here we report a methodology for maintaining strong ferromagnetism in insulating LaCoO3 (LCO) layers down to the thickness of a single unit cell. We find that the magnetic and electronic states of LCO are linked intimately to the structural parameters of adjacent "breathing lattice" SrCuO2 (SCO). As the dimensionality of SCO is reduced, the lattice constant elongates over 10% along the growth direction, leading to a significant distortion of the CoO6 octahedra, and promoting a higher spin state and long-range spin ordering. For atomically thin LCO layers, we observe surprisingly large magnetic moment (0.5 uB/Co) and Curie temperature (75 K), values larger than previously reported for any mono layer oxide. Our results demonstrate a strategy for creating ultra thin ferromagnetic oxides by exploiting atomic hetero interface engineering,confinement-driven structural transformation, and spin-lattice entanglement in strongly correlated materials., Comment: 24 pages, 5 figures, 1 supporting information with 13 figures

Published

2020

10. Strain-mediated high conductivity in ultrathin antiferromagnetic metallic nitrides

Author

Jin, Qiao, Cheng, Hu, Wang, Zhiwen, Zhang, Qinghua, Lin, Shan, Roldan, Manuel A., Zhao, Jiali, Wang, Jia-Ou, Chen, Shuang, He, Meng, Ge, Chen, Wang, Can, Lu, Hui-Bin, Guo, Haizhong, Gu, Lin, Tong, Xin, Zhu, Tao, Wang, Shanmin, Yang, Hongxin, Jin, Kui-juan, and Guo, Er-Jia

Subjects

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

Abstract

Strain engineering provides the ability to control the ground states and associated phase transition in the epitaxial films. However, the systematic study of intrinsic characters and their strain dependency in transition-metal nitrides remains challenging due to the difficulty in fabricating the stoichiometric and high-quality films. Here we report the observation of electronic state transition in highly crystalline antiferromagnetic CrN films with strain and reduced dimensionality. Shrinking the film thickness to a critical value of ~ 30 unit cells, a profound conductivity reduction accompanied by unexpected volume expansion is observed in CrN films. The electrical conductivity is observed surprisingly when the CrN layer as thin as single unit cell thick, which is far below the critical thickness of most metallic films. We found that the metallicity of an ultrathin CrN film recovers from an insulating behavior upon the removal of as-grown strain by fabrication of first-ever freestanding nitride films. Both first-principles calculations and linear dichroism measurements reveal that the strain-mediated orbital splitting effectively customizes the relatively small bandgap at the Fermi level, leading to exotic phase transition in CrN. The ability to achieve highly conductive nitride ultrathin films by harness strain-controlling over competing phases can be used for utilizing their exceptional characteristics., Comment: 24 pages, 5 figures

Published

2020

11. Spontaneous Formation of a Superconductor-Topological Insulator-Normal Metal Layered Heterostructure

Author

Wang, Yu-Qi, Wu, Xu, Wang, Ye-Liang, Shao, Yan, Lei, Tao, Wang, Jia-Ou, Zhu, Shi-Yu, Guo, Haiming, Zhao, Ling-Xiao, Chen, Gen-Fu, Nie, Simin, Weng, Hong-Ming, Ibrahim, Kurash, Dai, Xi, Fang, Zhong, and Gao, Hong-Jun

Subjects

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

Abstract

The discovery of graphene has spurred vigorous investigation of 2D materials, revealing a wide range of extraordinary properties and functionalities. 2D heterostructural materials have recently been fabricated by assembling isolated planes layer-by-layer in a desired sequence. Unusual properties and novel physical phenomena have been unveiled in such layered heterostructures. For example, Hofstadter's butterfly, an intriguing pattern of the energy states of Bloch electrons, was predicted several decades ago to be observable only under unfeasibly strong magnetic fields in conventional materials. But it has been observed recently under current experimental conditions in graphene/BN layered heterostructures, one of the outstanding new kinds of 2D materials. Moreover, another amazing physics phenomenon, Majorana fermions was predicted to exist in heterostructural systems consisting of a superconductor (SC) and a topological insulator (TI) Journal.

Published

2020