Your search keyword '"Lyu, Yingjie"' showing total 11 results

1. Oxygen Ion Pumping across Atomically Designed Oxide Heterointerfaces.

Author

Wu, Yongshun, Zhang, Yang, Zhang, Jianbing, Lyu, Yingjie, Li, Cong, Wu, Sijie, Wang, Yupu, Wang, Meng, Long, Youwen, Nan, Tianxiang, Yi, Di, Zhu, Junyi, He, Qing, Zhou, Shuyun, and Yu, Pu

Subjects

HETEROJUNCTIONS, CRYSTAL structure, TRANSITION temperature, CHEMICAL potential, HETEROSTRUCTURES

Abstract

Complex oxide heterointerfaces and heterostructures have demonstrated enormous emergent phenomena over the last decades, attributed to the reconstructions of mis‐matched crystalline structure, polarity, and spin ordering across the heterointerfaces. This work employs the heterostructures of La0.7Sr0.3MnO3 and CaFeO2.5 as model system to demonstrate an interface‐specific oxygen migration/reconstruction across the interfaces due to the mismatched chemical potential, which dramatically influences the ferromagnetic and electronic states of La0.7Sr0.3MnO3 layer. Specifically, the alternative stacking of octahedral (Oh) and tetrahedral (Td) layers in CaFeO2.5 are used to form two distinct heterointerfaces, namely the Oh‐Td and the Oh‐Oh interfaces with the adjacent La0.7Sr0.3MnO3 layer. Interestingly, the oxygen ion migrates toward opposite directions across the interface for these two cases, in which the CaFeO2.5 layer acts as an "oxygen pump" and manipulates the oxygen contents of its adjacent La0.7Sr0.3MnO3 layers. Such manipulation leads to a dramatically changed ferromagnetic transition temperature for the heterostructure with the Oh‐Td and Oh‐Oh interface. This work establishes a feasible and efficient strategy to control the oxygen ionic distribution through atomic‐scale interface design and opens up new opportunities to exploit emergent states at the complex oxide heterostructures through selective oxygen ion evolution. [ABSTRACT FROM AUTHOR]

Published

2024

2. Emergent zero-field anomalous Hall effect in a reconstructed rutile antiferromagnetic metal.

Author

Wang, Meng, Tanaka, Katsuhiro, Sakai, Shiro, Wang, Ziqian, Deng, Ke, Lyu, Yingjie, Li, Cong, Tian, Di, Shen, Shengchun, Ogawa, Naoki, Kanazawa, Naoya, Yu, Pu, Arita, Ryotaro, and Kagawa, Fumitaka

Subjects

ANOMALOUS Hall effect, RUTILE, MAGNETIC fields, DENSITY functional theory, METALS, CARRIER density

Abstract

The anomalous Hall effect (AHE) that emerges in antiferromagnetic metals shows intriguing physics and offers numerous potential applications. Magnets with a rutile crystal structure have recently received attention as a possible platform for a collinear-antiferromagnetism-induced AHE. RuO2 is a prototypical candidate material, however the AHE is prohibited at zero field by symmetry because of the high-symmetry [001] direction of the Néel vector at the ground state. Here, we show AHE at zero field in Cr-doped rutile, Ru0.8Cr0.2O2. The magnetization, transport and density functional theory calculations indicate that appropriate doping of Cr at Ru sites reconstructs the collinear antiferromagnetism in RuO2, resulting in a rotation of the Néel vector from [001] to [110] while maintaining a collinear antiferromagnetic state. The AHE with vanishing net moment in the Ru0.8Cr0.2O2 exhibits an orientation dependence consistent with the [110]-oriented Hall vector. These results demonstrate that material engineering by doping is a useful approach to manipulate AHE in antiferromagnetic metals. The anomalous Hall effect is typically associated with ferromagnets and referred to as anomalous due to its persistence even after the applied magnetic field is removed, due to the net magnetization of the ferromagnet. Recently there has been much interest in antiferromagnets that can host an anomalous Hall effect, despite a vanishing magnetization, and here, Wang et al observe an anomalous Hall effect in collinearly antiferromagnetic chromium doped RuO2. [ABSTRACT FROM AUTHOR]

Published

2023

3. Coexistence of Both Localized Electronic States and Electron Gas at Rutile TiO2 Surfaces.

Author

Shen, Shengchun, Wang, Meng, Zhang, Yang, Lyu, Yingjie, Tian, Di, Gao, Chang, Long, Youwen, Zhao, Jin, and Yu, Pu

Published

2023

4. Manipulation of the Ferromagnetism in LaCoO3 Thin Films Through Cation‐Stoichiometric Engineering.

Author

Huang, Tongtong, Lyu, Yingjie, Huyan, Huaixun, Ni, Jinyang, Saremi, Sahar, Wang, Yujia, Yan, Xingxu, Yi, Di, He, Qing, Martin, Lane W., Xiang, Hongjun, Pan, Xiaoqing, and Yu, Pu

Subjects

THIN films, FERROMAGNETISM, CRYSTAL structure, ENGINEERING, MAGNETIZATION

Abstract

Spin‐state transitions are an important research topic in complex oxides with the diverse magnetic states involved. In particular, the low‐spin to high‐spin transition in LaCoO3 thin films has drawn a wide range of attention due to the emergent ferromagnetic state. Although various mechanisms (e.g., structural distortion, oxygen‐vacancy formation, spin‐state ordering) have been proposed, an understanding of what really underlies the emergent ferromagnetism remains elusive. Here, the ferromagnetism in LaCoO3 thin films is systematically modulated by varying the oxygen pressure during thin‐film growth. Although the samples show dramatic different magnetization, their cobalt valence state and perovskite crystalline structure remain almost unchanged, ruling out the scenarios of both oxygen‐vacancy and spin‐ordering. This work provides compelling evidence that the tetragonal distortion due to the tensile strain significantly modifies the orbital occupancy, leading to a low‐spin to high‐spin transition with emergent ferromagnetism, while samples grown at reduced pressure demonstrate a pronounced lattice expansion due to cation‐off‐stoichiometry, which suppresses the tetragonal distortion and the consequent magnetization. This result not only provides important insight for the understanding of exotic ferromagnetism in LaCoO3 thin films, but also identifies a promising strategy to design electronic states in complex oxides through cation‐stoichiometry engineering. [ABSTRACT FROM AUTHOR]

Published

2023

5. Enhanced Magnetization in CoFe2O4 Through Hydrogen Doping.

Author

Li, Zhuolu, Lyu, Yingjie, Ran, Zhao, Wang, Yujia, Zhang, Yang, Lu, Nianpeng, Wang, Meng, Sassi, Michel, Ha, Thai Duy, T. N'Diaye, Alpha, Shafer, Padraic, Pearce, Carolyn, Rosso, Kevin, Arenholz, Elke, Juang, Jenh‐Yih, He, Qing, Chu, Ying‐Hao, Luo, Weidong, and Yu, Pu

Subjects

MAGNETIZATION, ANTISITE defects, HYDROGEN ions, LEAD, HYDROGEN

Abstract

Magnetic spinel oxides have attracted extensive research interest due to their rich physics and wide range of applications. However, these materials invariably suffer suppressed magnetization, due to structural imperfections (e.g., disorder, anti‐site defects, etc.). Herein, a dramatic enhanced magnetization is obtained with an increasement of 5 µB/u.c in CoFe2O4 (CFO) through ionic liquid gating induced hydrogen doping. The intercalated hydrogen ions lead to both distinct lattice expansion of ≈0.7% and notable Fe valence state reduction through electron doping, in which ≈17% Fe3+ is reduced into Fe2+. These facts collectively trigger a site‐specific spin‐flip on tetrahedrally coordinated Co2+ sites that enhances the net ferrimagnetic moment nearly to its theoretical maximum for perfect CFO. [ABSTRACT FROM AUTHOR]

Published

2023

6. Facile Pathways to Synthesize Perovskite Strontium Cobalt Oxides.

Author

Lu, Sicheng, Yin, Fang, Wang, Yujia, Lu, Nianpeng, Gao, Lei, Peng, Huining, Lyu, Yingjie, Long, Youwen, Li, Jia, and Yu, Pu

Subjects

COBALT oxides, PHASE transitions, PEROVSKITE, STRONTIUM oxide, DENSITY functional theory, AQUEOUS electrolytes, LEAD oxides, COBALT

Abstract

Topotactic phase transition obtains extensive research attention due to its associated rich physics as well as a promising potential application. Particularly, the oxygen incorporation into brownmillerite oxides leads to the structural transition into perovskite oxides with distinct magnetic and electronic properties. Using brownmillerite SrCoO2.5 (BM‐SCO), two novel pathways are revealed to achieve the topotactic phase transition into its corresponding perovskite SrCoO3 (P‐SCO). It is demonstrated that by using aqueous alkali as the electrolyte during gating, the negative biased voltage triggers a rapid transition into P‐SCO, which is attributed to the presence of strong oxidizing hydroxyl radicals. While surprisingly, it is observed that the acid solution with rich protons can also trigger an unexpected phase transition from BM‐SCO into P‐SCO in a much faster manner. With density functional theory calculations, this transition is elucidated as a proton‐assist ionic disproportionation, in which the Co ions are simultaneously oxidized and reduced, while the latter one is dissolved within the solution. These case studies not only achieve a deep understanding of the structural phase transition in BM‐SCO but also shed new light on the topotactic phase transition of complex oxides. [ABSTRACT FROM AUTHOR]

Published

2023

7. A Generic Sacrificial Layer for Wide‐Range Freestanding Oxides with Modulated Magnetic Anisotropy.

Author

Peng, Huining, Lu, Nianpeng, Yang, Shuzhen, Lyu, Yingjie, Liu, Zhiwei, Bu, Yifan, Shen, Shengchun, Li, Mingqiang, Li, Zhuolu, Gao, Lei, Lu, Sicheng, Wang, Meng, Cao, Hui, Zhou, Hua, Gao, Peng, Chen, Hanghui, and Yu, Pu

Subjects

THIN films, CRYSTAL structure, MAGNETIC properties, ACETIC acid, FLEXIBLE structures, CARBONATED beverages

Abstract

Freestanding oxide nanomembranes have promising applications because of their novel electronic states and flexible crystalline structures. Several materials have been developed as sacrificial layers to exfoliate thin films from substrates via wet‐etching. However, these materials face great challenges in terms of either complicated crystalline structures or corrosive solutions. Here, a new sacrificial material, SrCoO2.5, is presented, which can be coherently grown with wide‐range strains and crystalline orientations and is also soluble in eco‐friendly solutions such as acetic acid, vinegar, and even carbonated drinks. With SrCoO2.5 as the sacrificial layer, high‐quality freestanding ferromagnetic SrRuO3 membranes are achieved from wide‐range epitaxial strains and different crystalline orientations. By investigating the evolution of the magnetic properties of these samples, it is discovered that epitaxial strain causes a distinct modification of the magnetic anisotropy of (001)pc‐oriented SrRuO3 samples, while its influence on the (110)pc and (111)pc samples is insignificant. This study not only demonstrates the freestanding SrRuO3 as a promising material for flexible spintronic devices, but also offers a great opportunity to engineer a wide range of strained and oriented complex oxides for novel freestanding electronics using this newly developed sacrificial material. [ABSTRACT FROM AUTHOR]

Published

2022

8. Reversible manipulation of the magnetic state in SrRuO3 through electric-field controlled proton evolution.

Author

Li, Zhuolu, Shen, Shengchun, Tian, Zijun, Hwangbo, Kyle, Wang, Meng, Wang, Yujia, Bartram, F. Michael, He, Liqun, Lyu, Yingjie, Dong, Yongqi, Wan, Gang, Li, Haobo, Lu, Nianpeng, Zang, Jiadong, Zhou, Hua, Arenholz, Elke, He, Qing, Yang, Luyi, Luo, Weidong, and Yu, Pu

Subjects

MAGNETIC transitions, CARRIER density, PROTONS, HALL effect, FERROMAGNETIC materials, PROTON transfer reactions

Abstract

Ionic substitution forms an essential pathway to manipulate the structural phase, carrier density and crystalline symmetry of materials via ion-electron-lattice coupling, leading to a rich spectrum of electronic states in strongly correlated systems. Using the ferromagnetic metal SrRuO3 as a model system, we demonstrate an efficient and reversible control of both structural and electronic phase transformations through the electric-field controlled proton evolution with ionic liquid gating. The insertion of protons results in a large structural expansion and increased carrier density, leading to an exotic ferromagnetic to paramagnetic phase transition. Importantly, we reveal a novel protonated compound of HSrRuO3 with paramagnetic metallic as ground state. We observe a topological Hall effect at the boundary of the phase transition due to the proton concentration gradient across the film-depth. We envision that electric-field controlled protonation opens up a pathway to explore novel electronic states and material functionalities in protonated material systems. Ionic substitution is a useful way to manipulate structural, electronic, magnetic phase transitions in strongly correlated materials. Here, the authors report electric-field controlled protonation in SrRuO3, resulting in a large structural expansion and a ferromagnetic-to-paramagnetic phase transition. [ABSTRACT FROM AUTHOR]

Published

2020

9. Tuning the electronic properties of epitaxial strained CaFeO3−δ thin films.

Author

Huang, Tongtong, Wang, Yujia, Li, Haobo, Wang, Meng, Lyu, Yingjie, Shen, Shengchun, Lu, Nianpeng, He, Qing, and Yu, Pu

Subjects

EPITAXY, THIN films, STRAINS & stresses (Mechanics), X-ray absorption spectra, PEROVSKITE

Abstract

Strain engineering of transition metal oxides due to their desirable properties has long been a focal point in both physics and material sciences. Here, we investigate the strain dependence of electronic and optical properties of the high valence iron-based perovskite CaFeO3−δ. Using substrates with various lattice constants, we achieve a wide range of tunable epitaxial strain states in CaFeO3−δ thin films ranging from compressive −0.37% to tensile 3.58%. Electrical transport and optical absorption measurements demonstrate a distinct strain-dependent behavior, in which larger tensile strain leads to higher electrical resistivity and a larger optical bandgap. We attribute these modulations to tensile strain suppressed p-d hybridization in CaFeO3−δ, as evidenced by soft X-ray absorption spectra measurements. [ABSTRACT FROM AUTHOR]

Published

2019

10. Electric Field–Controlled Multistep Proton Evolution in HxSrCoO2.5 with Formation of H–H Dimer.

Author

Li, Hao‐Bo, Lou, Feng, Wang, Yujia, Zhang, Yang, Zhang, Qinghua, Wu, Dong, Li, Zhuolu, Wang, Meng, Huang, Tongtong, Lyu, Yingjie, Guo, Jingwen, Chen, Tianzhe, Wu, Yang, Arenholz, Elke, Lu, Nianpeng, Wang, Nanlin, He, Qing, Gu, Lin, Zhu, Jing, and Nan, Ce‐Wen

Subjects

PROTONS, SCANNING transmission electron microscopy

Abstract

Ionic evolution–induced phase transformation can lead to wide ranges of novel material functionalities with promising applications. Here, using the gating voltage during ionic liquid gating as a tuning knob, the brownmillerite SrCoO2.5 is transformed into a series of protonated HxSrCoO2.5 phases with distinct hydrogen contents. The unexpected electron to charge‐neutral doping crossover along with the increase of proton concentration from x = 1 to 2 suggests the formation of exotic charge neutral H–H dimers for higher proton concentration, which is directly visualized at the vacant tetrahedron by scanning transmission electron microscopy and then further supported by first principles calculations. Although the H–H dimers cause no change of the valency of Co2+ ions, they result in clear enhancement of electronic bandgap and suppression of magnetization through lattice expansion. These results not only reveal a hydrogen chemical state beyond anion and cation within the complex oxides, but also suggest an effective pathway to design functional materials through tunable ionic evolution. [ABSTRACT FROM AUTHOR]

Published

2019

11. Manipulate the Electronic and Magnetic States in NiCo2O4 Films through Electric‐Field‐Induced Protonation at Elevated Temperature.

Author

Wang, Meng, Sui, Xuelei, Wang, Yujia, Juan, Yung‐Hsiang, Lyu, Yingjie, Peng, Huining, Huang, Tongtong, Shen, Shengchun, Guo, Chenguang, Zhang, Jianbing, Li, Zhuolu, Li, Hao‐Bo, Lu, Nianpeng, N'Diaye, Alpha T., Arenholz, Elke, Zhou, Shuyun, He, Qing, Chu, Ying‐Hao, Duan, Wenhui, and Yu, Pu

Published

2019