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8 results on '"Guo, Mingda"'

1. Unveiling the spin evolution in van der Waals antiferromagnets via magneto-exciton effects.

Author

Wang, Xingzhi, Tan, Qishuo, Li, Tie, Lu, Zhengguang, Cao, Jun, Ge, Yanan, Zhao, Lili, Tang, Jing, Kitadai, Hikari, Guo, Mingda, Li, Yun-Mei, Xu, Weigao, Cheng, Ran, Smirnov, Dmitry, and Ling, Xi

Abstract

Among the fascinating phenomena observed in two-dimensional (2D) magnets, the magneto-exciton effect stands out as a pivotal link between optics and magnetism. Although the excitonic effect has been revealed and exhibits a considerable correlation with the spin structures in certain 2D magnets, the underlying mechanism of the magneto-exciton effect remains underexplored, especially under high magnetic fields. Here we perform a systematic investigation of the spin-exciton coupling in 2D antiferromagnetic NiPS3 under high magnetic fields. When an in-plane magnetic field is applied, the exceptional sharp excitonic emission at ~1.4756 eV exhibits a Zeeman-like splitting with g ≈ 2.0, experimentally identifying the exciton as an excitation of dominant triplet-singlet character. By examining the polarization of excitonic emission and simulating the spin evolution, we further verify the correlation between excitonic emission and Néel vector in NiPS3. Our work elucidates the mechanism behind the spin-exciton coupling in NiPS3 and establishes a strategy for optically probing the spin evolutions in 2D magnets.

Published
2024

2. Field-Assisted Sub-Terahertz Spin Pumping and Auto-Oscillation in NiO

Author

Guo, Mingda and Cheng, Ran

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

Spin pumping converting sub-terahertz electromagnetic waves to DC spin currents has recently been demonstrated in antiferromagnets (AFMs) with easy-axis magnetic anisotropy. However, easy-plane AFMs such as NiO, which are easier to prepare experimentally, are considered to be bad candidates for spin pumping because the N\'{e}el vector oscillation is linearly polarized, placing a major restriction on the material choice for practical applications. Through a case study of NiO, we show that an applied magnetic field below the spin-flop transition can substantially modify the polarization of the resonance eigenmodes, which enables coherent sub-terahertz spin pumping as strong as that in easy-axis AFMs. In addition, we find that an applied magnetic field can significantly reduce the threshold of N\'{e}el vector auto-oscillation triggered by spin-transfer torques. These prominent field-assisted effects can greatly facilitate spintronic device engineering in the sub-terahertz frequency regime.

Published
2022
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3. Manipulating Ferrimagnets by Fields and Currents

Author

Guo, Mingda, Zhang, Hantao, and Cheng, Ran

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Ferrimagnets (FIMs) can function as high-frequency antiferromagnets while being easy to detect as ferromagnets, offering unique opportunities for ultrafast device applications. While the physical behavior of FIMs near the compensation point has been widely studied, there lacks a generic understanding of FIMs where the ratio of sublattice spins can vary freely between the ferromagnetic and antiferromagnetic limits. Here we investigate the physical properties of a model two-sublattice FIM manipulated by static magnetic fields and current-induced torques. By continuously varying the ratio of sublattice spins, we clarify how the dynamical chiral modes in an FIM are intrinsically connected to their ferro- and antiferromagnetic counterparts, which reveals unique features not visible near the compensation point. In particular, we find that current-induced torques can trigger spontaneous oscillation of the terahertz exchange mode. Compared with its realization in antiferromagnets, a spin-torque oscillator using FIMs not only has a reduced threshold current density but also can be self-stabilized, obviating the need for dynamic feedback., Comment: 9 pages and 7 figures

Published
2021
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4. Spin Pumping of an Easy-Plane Antiferromagnet Enhanced by Dzyaloshinskii-Moriya Interaction

Author

Wang, Hailong, Xiao, Yuxuan, Guo, Mingda, Lee-Wong, Eric, Yan, Gerald Q., Cheng, Ran, and Du, Chunhui Rita

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

Recently, antiferromagnets have received revived interest due to their significant potential for developing next-generation ultrafast magnetic storage. Here we report dc spin pumping by the acoustic resonant mode in a canted easy-plane antiferromagnet {\alpha}-Fe2O3 enabled by the Dzyaloshinskii-Moriya interaction. Systematic angle and frequency dependent measurements demonstrate that the observed spin pumping signals arise from resonance-induced spin injection and inverse spin Hall effect in {\alpha}-Fe2O3/metal heterostructures, mimicking the behavior of spin pumping in conventional ferromagnet/nonmagnet systems. The pure spin current nature is further corroborated by reversal of the polarity of spin pumping signals when the spin detector is switched from platinum to tungsten which has an opposite sign of the spin Hall angle. Our results highlight the potential opportunities offered by the low-frequency acoustic resonant mode in canted easy-plane antiferromagnets for developing next-generation, functional spintronic devices., Comment: 15 pages, 5 figures

Published
2021
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5. Efficient Spin-Pumping in Ultrafast Magnetic Systems

Author

Guo, Mingda

Subjects
Theoretical physics, Antiferromagnets, Ferrimagnets, Ferromagnets, Magnetic Materials, Spin Pumping, Spintronics
Abstract

Spintronics investigates the interactions between magnetization dynamics and electron transport, particularly in ferromagnetic (FM) materials. My dissertation expands the realm of spintronics to antiferromagnetic (AF) materials, which are relatively unexplored and lack substantial theoretical frameworks. It specifically examines dc spin pumping in canted easy-plane antiferromagnet α-Fe2O3, facilitated by the Dzyaloshinskii-Moriya interaction.Additionally, the dissertation explores the effects of magnetic fields on NiO below the spin-flop transition, demonstrating robust sub-terahertz spin pumping akin to that in easy-axis AFs by altering the resonance polarization through field application. The study also shows that an external magnetic field can significantly reduce the threshold for Néel vector auto-oscillation via spin-transfer torques, enhancing the potential for innovative device applications in the sub-terahertz spectrum.This comprehensive study not only deepens our understanding of AF spintronics but also paves the way for the development of new spintronic devices leveraging the unique properties of antiferromagnetic materials. Moreover, the dissertation broadens the scope of spintronics by extending its examination to the physical properties of two-sublattice ferrimagnets (FIMs) and antiferromagnetic van der Waals materials within two-dimensional (2D) layered systems.

Published
2024

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