研究者詳細

顔写真

タン ピン
Tang Ping
Tang Ping
所属
高等研究機構材料科学高等研究所 材料物理グループ
職名
特任助教(研究)
学位

  • 博士(工学)(中国科学院大学)

e-Rad 研究者番号
90927427

経歴 2

  • 2021年4月 ~ 継続中
    AIMR, Tohoku University

  • 2020年11月 ~ 2021年3月
    Institute for Materials Research, Tohoku University

学歴 3

  • Institute of Physics, Chinese Academy of Sciences Ph.D

    2015年9月 ~ 2020年7月

  • The University of Arizona Department of Physics Visiting student

    2017年12月 ~ 2019年12月

  • Jilin University Department of Physics Bachelor

    2011年9月 ~ 2015年7月

研究キーワード 4

  • Multiferroics

  • Ferroelectric materials

  • Spintronics and magnetism

  • Condensed matter theory

研究分野 1

  • 自然科学一般 / 数理物理、物性基礎 /

受賞 1

  1. Core Research Cluster for Spintronics Award

    2023年11月 Tohoku University Spintronic analog of ferroelectric materials

論文 29

  1. Giant magnon-driven magnetothermal transport in magnetic multilayers

    Ping Tang, Ken-ichi Uchida, Gerrit E. W. Bauer

    Physical Review B 2025年5月19日

    DOI: 10.1103/PhysRevB.111.L180407  

  2. Unconventional Spin Hall Magnetoresistance in Noncollinear Antiferromagnet/Heavy Metal Stacks 査読有り

    Uchimura, T., Han, J., Tang, P., Yoon, J.-Y., Takeuchi, Y., Yamane, Y., Kanai, S., Bauer, G.E.W., Ohno, H., Fukami, S.

    Physical Review Letters 134 (9) 2025年3月3日

    DOI: 10.1103/PhysRevLett.134.096701  

    ISSN:0031-9007 1079-7114

  3. Role of Disorder in the Intrinsic Orbital Hall Effect 査読有り

    Ping Tang, Gerrit E. W. Bauer

    Physical Review Letters 2024年10月30日

    DOI: 10.1103/PhysRevLett.133.186302  

  4. Thermal and Coherent Spin Pumping by Noncollinear Antiferromagnets 査読有り

    Ping Tang, Gerrit E. W. Bauer

    Physical Review Letters 2024年7月18日

    DOI: 10.1103/PhysRevLett.133.036701  

  5. Surface and volume modes of polarization waves in ferroelectric films 査読有り

    Rodr{\'i}guez-Su{\'a}rez, R.L., Zhou, X.-H., Cai, C.Y., Tang, P., Yu, T., Bauer, G.E.W., Rezende, S.M.

    Physical Review B 109 (13) 2024年4月19日

    DOI: 10.1103/PhysRevB.109.134307  

    ISSN:2469-9950 2469-9969

  6. Electric analog of magnons in order-disorder ferroelectrics

    Ping Tang, Gerrit E. W. Bauer

    Physical Review B 109 (6) 2024年2月20日

    出版者・発行元: American Physical Society (APS)

    DOI: 10.1103/physrevb.109.l060301  

    ISSN:2469-9950

    eISSN:2469-9969

  7. Ultrafast switching dynamics of the ferroelectric order in stacking-engineered ferroelectrics 査読有り

    Ri He, Bingwen Zhang, Hua Wang, Lei Li, Ping Tang, Gerrit Bauer, Zhicheng Zhong

    Acta Materialia 262 119416-119416 2024年1月

    出版者・発行元: Elsevier {BV}

    DOI: 10.1016/j.actamat.2023.119416  

    ISSN:1359-6454

  8. Soft Magnons in Anisotropic Ferromagnets 査読有り

    G. E. W. Bauer, P. Tang, M. Elyasi, Y. M. Blanter, B. J. van Wees

    Physical Review B 2023年8月28日

    出版者・発行元: arXiv

    DOI: 10.48550/ARXIV.2304.10709   10.1103/PhysRevB.108.064431  

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    We discuss spin-wave transport in anisotropic ferromagnets with an emphasis on the zeroes of the band edges as a function of a magnetic field. An associated divergence of the magnon spin should be observable by enhanced magnon conductivities in non-local experiments, especially in two-dimensional ferromagnets.

  9. Surface Ferron Excitations in Ferroelectrics and Their Directional Routing 査読有り

    Xi-Han Zhou, Chengyuan Cai, Ping Tang, R. L. Rodríguez-Suárez, Sergio M. Rezende, Gerrit E. W. Bauer, Tao Yu

    Chinese Physics Letters 40 (8) 087103-087103 2023年8月1日

    出版者・発行元: {IOP} Publishing

    DOI: 10.1088/0256-307x/40/8/087103  

    ISSN:0256-307X 1741-3540

    eISSN:1741-3540

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    <jats:p>The duality between electric and magnetic dipoles inspires recent comparisons between ferronics and magnonics. Here we predict surface polarization waves or “ferrons” in ferroelectric insulators, taking the long-range dipolar interaction into account. We predict properties that are strikingly different from the magnetic counterpart, i.e. the surface Damon–Eshbach magnons in ferromagnets. The dipolar interaction pushes the ferron branch with locked circular polarization and momentum to the ionic plasma frequency. The low-frequency modes are on the other hand in-plane polarized normal to their wave vectors. The strong anisotropy of the lower branch renders directional emissions of electric polarization and chiral near fields when activated by a focused laser beam, allowing optical routing in ferroelectric devices.</jats:p>

  10. Long-distance magnon transport in the van der Waals antiferromagnet 査読有り

    Dennis Kelvin de Wal, Arnaud Iwens, Tian Liu, Ping Tang, Gerrit Bauer, Bart J. van Wees

    Physical Review B 107 (18) 2023年5月11日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.107.l180403  

    ISSN:2469-9950 2469-9969

  11. Sliding Phase Transition in Ferroelectric van der Waals Bilayers 査読有り

    Ping Tang, Gerrit Bauer

    Physical Review Letters 130 (17) 2023年4月25日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevlett.130.176801  

    ISSN:0031-9007 1079-7114

  12. Nonlocal drag thermoelectricity generated by ferroelectric van der Waals heterostructures 査読有り

    Ping Tang, Ken-ichi Uchida, Gerrit Bauer

    Physical Review B 107 (12) 2023年3月21日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.107.l121406  

    ISSN:2469-9950 2469-9969

  13. Electric field–dependent phonon spectrum and heat conduction in ferroelectrics 査読有り

    Brandi Wooten, Ryo Iguchi, Ping Tang, Joon Sang Kang, Ken-ichi Uchida, Gerrit Bauer, Joseph P. Heremans

    Science Advances 9 (5) 2023年2月

    出版者・発行元: American Association for the Advancement of Science ({AAAS})

    DOI: 10.1126/sciadv.add7194  

    ISSN:2375-2548

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    <jats:p> This article shows experimentally that an external electric field affects the velocity of the longitudinal acoustic phonons ( <jats:italic>v</jats:italic> <jats:sub>LA</jats:sub> ), thermal conductivity (κ), and diffusivity ( <jats:italic>D</jats:italic> ) in a bulk lead zirconium titanate–based ferroelectric. Phonon conduction dominates κ, and the observations are due to changes in the phonon dispersion, not in the phonon scattering. This gives insight into the nature of the thermal fluctuations in ferroelectrics, namely, phonons labeled ferrons that carry heat and polarization. It also opens the way for phonon-based electrically driven all-solid-state heat switches, an enabling technology for solid-state heat engines. A quantitative theoretical model combining piezoelectric strain and phonon anharmonicity explains the field dependence of <jats:italic>v</jats:italic> <jats:sub>LA</jats:sub> , κ, and <jats:italic>D</jats:italic> without any adjustable parameters, thus connecting thermodynamic equilibrium properties with transport properties. The effect is four times larger than previously reported effects, which were ascribed to field-dependent scattering of phonons. </jats:p>

  14. Prediction of a first-order phase transition in two-dimensional ferromagnets in the presence of random fields 査読有り

    Essa Ibrahim, Ping Tang, Shufeng Zhang

    Journal of Magnetism and Magnetic Materials 564 169993-169993 2022年12月

    出版者・発行元: Elsevier {BV}

    DOI: 10.1016/j.jmmm.2022.169993  

    ISSN:0304-8853

  15. Excitations of the ferroelectric order 査読有り

    Ping Tang, Ryo Iguchi, Ken-ichi Uchida, Gerrit Bauer

    Physical Review B 106 (8) 2022年8月8日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.106.l081105  

    ISSN:2469-9950 2469-9969

  16. Thermoelectric Polarization Transport in Ferroelectric Ballistic Point Contacts 査読有り

    Ping Tang, Ryo Iguchi, Ken-ichi Uchida, Gerrit Bauer

    Physical Review Letters 128 (4) 2022年1月25日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevlett.128.047601  

    ISSN:0031-9007 1079-7114

  17. Magnonics vs. Ferronics 査読有り

    Gerrit Bauer, Ping Tang, Ryo Iguchi, Ken-ichi Uchida

    Journal of Magnetism and Magnetic Materials 541 168468-168468 2022年1月

    出版者・発行元: Elsevier {BV}

    DOI: 10.1016/j.jmmm.2021.168468  

    ISSN:0304-8853

  18. Magnon junction effect in Y3Fe5O12/CoO/Y3Fe5O12 insulating heterostructures 査読有り

    Wenqing He, Hao Wu, Chenyang Guo, caihua wan, Zhao Mingkun, Yaowen Xing, Ping Tang, Zhengren Yan, Jihao Xia, Tian Yu, Xiu-Feng Han

    Applied Physics Letters 119 (21) 212410-212410 2021年11月22日

    出版者・発行元: {AIP} Publishing

    DOI: 10.1063/5.0074335  

    ISSN:0003-6951 1077-3118

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    <jats:p>Magnonics as an emerging frontier of spintronics aims using magnons to deliver information free from electron scattering and as-induced Joule heating. In general, magnon currents can be excited both thermally and electrically in magnetic insulators by applying a current in an adjacent heavy-metal layer. Here, we report another kind of magnon junctions (MJs) composed of Y3Fe5O12/CoO/Y3Fe5O12 heterostructures, in which Y3Fe5O12 and CoO are, respectively, ferrimagnetic and antiferromagnetic insulators. A temperature gradient can drive a high (low) magnon current via the spin Seebeck effect when the Y3Fe5O12 layers in an MJ are configured at the parallel (antiparallel) state, showing a spin valve-like behavior. Electrically injected magnon current could also be controlled by the MJs, contributing to a magnon-mediate nonlocal spin Hall magnetoresistance (SMR). Furthermore, compared with its NiO counterpart, both the magnon junction and magnon-mediate SMR effects can be clearly observed at room temperature for the CoO-based magnon junctions, which can possibly be applied as a building block for room-temperature magnon-based memory or logic devices.</jats:p>

  19. Quantum theory of spin-torque driven magnetization switching 査読有り

    Ping Tang, Xiu-Feng Han, Shufeng Zhang

    Physical Review B 103 (9) 2021年3月26日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.103.094442  

    ISSN:2469-9950 2469-9969

  20. Current‐Induced Spin Torques on Single GdFeCo Magnetic Layers 査読有り

    David Céspedes‐Berrocal, Heloïse Damas, Sébastien Petit-Watelot, Davide Maccariello, Ping Tang, Aldo Arriola‐Córdova, Pierre Vallobra, Yong Xu, Jean‐Loïs Bello, Elodie Martin, Sylvie Migot, Jaafar Ghanbaja, Shufeng Zhang, Michel Hehn, Stéphane Mangin, Christos Panagopoulos, Vincent Cros, ALBERT FERT, Juan-Carlos Rojas-Sánchez

    Advanced Materials 33 (12) 2021年3月

    出版者・発行元: Wiley

    DOI: 10.1002/adma.202007047  

    ISSN:0935-9648 1521-4095

    eISSN:1521-4095

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    <jats:title>Abstract</jats:title><jats:p>Spintronics exploit spin‐orbit coupling (SOC) to generate spin currents, spin torques, and, in the absence of inversion symmetry, Rashba and Dzyaloshinskii–Moriya interactions. The widely used magnetic materials, based on 3d metals such as Fe and Co, possess a small SOC. To circumvent this shortcoming, the common practice has been to utilize the large SOC of nonmagnetic layers of 5d heavy metals (HMs), such as Pt, to generate spin currents and, in turn, exert spin torques on the magnetic layers. Here, a new class of material architectures is introduced, excluding nonmagnetic 5d HMs, for high‐performance spintronics operations. Very strong current‐induced torques exerted on single ferrimagnetic GdFeCo layers, due to the combination of large SOC of the Gd 5d states and inversion symmetry breaking mainly engineered by interfaces, are demonstrated. These “self‐torques” are enhanced around the magnetization compensation temperature and can be tuned by adjusting the spin absorption outside the GdFeCo layer. In other measurements, the very large emission of spin current from GdFeCo, 80% (20%) of spin anomalous Hall effect (spin Hall effect) symmetry is determined. This material platform opens new perspectives to exert “self‐torques” on single magnetic layers as well as to generate spin currents from a magnetic layer.</jats:p>

  21. Spin transport and dynamic properties of two-dimensional spin-momentum locked states 査読有り

    Ping Tang, Xiufeng Han, Shufeng Zhang

    EPL (Europhysics Letters) 130 (5) 58001-58001 2020年6月30日

    出版者・発行元: {IOP} Publishing

    DOI: 10.1209/0295-5075/130/58001  

    ISSN:1286-4854

    eISSN:1286-4854

  22. A nonlocal spin Hall magnetoresistance in a platinum layer deposited on a magnon junction 査読有り

    C. Y. Guo, C. H. Wan, W. Q. He, M. K. Zhao, Z. R. Yan, Y. W. Xing, X. Wang, P. Tang, Y. Z. Liu, S. Zhang, Yaowen LIU, Xiu-Feng Han

    Nature Electronics 3 (6) 304-308 2020年6月15日

    出版者・発行元: Springer Science and Business Media {LLC}

    DOI: 10.1038/s41928-020-0425-9  

    ISSN:2520-1131

  23. Coherent Resonant Tunneling through Double Metallic Quantum Well States 査読有り

    Bingshan Tao, Caihua Wan, Ping Tang, Jiafeng Feng, Hongxiang Wei, Xiao Wang, Stéphane Andrieu, Hongxin Yang, Mairbek Chshiev, Xavier Devaux, Thomas Hauet, François Montaigne, Stéphane Mangin, Michel Hehn, Daniel Lacour, Xiu-Feng Han, Yuan LU

    Nano Letters 19 (5) 3019-3026 2019年5月8日

    出版者・発行元: American Chemical Society ({ACS})

    DOI: 10.1021/acs.nanolett.9b00205  

    ISSN:1530-6984 1530-6992

  24. Magnon resonant tunneling effect in double-barrier insulating magnon junctions and magnon field effect transistor 査読有り

    Ping Tang, X. F. Han

    Physical Review B 99 (5) 2019年2月1日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.99.054401  

    ISSN:2469-9950 2469-9969

  25. Magnon valves based on YIG/NiO/YIG all-insulating magnon junctions 査読有り

    C. Y. Guo, C. H. Wan, X. Wang, C. Fang, P. Tang, W. J. Kong, M. K. Zhao, L. N. Jiang, B. S. Tao, G. Q. Yu, X. F. Han

    Physical Review B 98 (13) 2018年10月17日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.98.134426  

    ISSN:2469-9950 2469-9969

  26. Ultrahigh Tunneling-Magnetoresistance Ratios in Nitride-Based Perpendicular Magnetic Tunnel Junctions from First Principles 査読有り

    Baishun Yang, Lingling Tao, Leina Jiang, Weizhao Chen, Ping Tang, Yu Yan, Xiufeng Han

    Physical Review Applied 9 (5) 2018年5月14日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevapplied.9.054019  

    ISSN:2331-7019

  27. First-principles study of perpendicular magnetic anisotropy in ferrimagnetic D22-Mn3X (X = Ga, Ge) on MgO and SrTiO3 査読有り

    B. S. Yang, L. N. Jiang, W. Z. Chen, P. Tang, J. Zhang, X.-G. Zhang, Y. Yan, X. F. Han

    Applied Physics Letters 112 (14) 2018年4月2日

    出版者・発行元: AIP Publishing

    DOI: 10.1063/1.5013667  

    ISSN:0003-6951

    eISSN:1077-3118

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    The magnetic anisotropy energy (MAE) of bulk D022-Mn3X (X = Ga, Ge), Mn3X/MgO, and Mn3X/STiO3(STO) heterostructures is calculated from first principles calculations. The main source of the large perpendicular magnetic anisotropy (PMA) of bulk Mn3X is identified as Mn atoms in the Mn-Mn layer. In the four heterostructures, the magnetic moment of interfacial Mn atoms was reversed when Mn3X was epitaxially grown on MgO and STO substrates. More importantly, a large in-plane tensile strain induced by lattice mismatch between Mn3X and MgO significantly changes the MAE, explaining the difficulty in experiments to obtain PMA in epitaxial Mn3X/MgO. Furthermore, interface and surface Mn atoms also help to enhance the PMA of Mn3X/STO (MgO) heterostructures due to dxy and dz2 states changing from occupied states in bulk Mn3X to unoccupied states in the interface (surface) Mn of the heterostructures. These results suggest that the PMA of manganese compound heterostructures can be produced by decreasing the lattice mismatch with substrates and will guide the search for ultrathin manganese compound films with high PMA epitaxially grown on substrates for the application of spintronic devices.

  28. Magneto-Seebeck effect in spin valves 査読有り

    X. M. Zhang, C. H. Wan, H. Wu, P. Tang, Z. H. Yuan, Q. T. Zhang, X. Zhang, B. S. Tao, C. Fang, Dr. Muhammad Irfan

    Journal of Applied Physics 122 (14) 2017年10月14日

    出版者・発行元: {AIP} Publishing

    DOI: 10.1063/1.4991647  

    ISSN:0021-8979 1089-7550

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    <jats:p>The magneto-Seebeck (MS) effect, which is also called magneto-thermo-power, was observed in Co/Cu/Co and NiFe/Cu/Co spin valves. Their Seebeck coefficients in the parallel state were larger than those in the antiparallel state, and the MS ratio defined as (SAP -SP)/SP could reach –9% in our case. The MS effect originated not only from trivial giant magnetoresistance but also from spin current generated due to spin-polarized thermoelectric conductivity of ferromagnetic materials and subsequent modulation of the spin current by different spin configurations in spin valves. A simple Mott two-channel model reproduced a –11% MS effect for the Co/Cu/Co spin valves, qualitatively consistent with our observations. The MS effect could be applied for simultaneously sensing the temperature gradient and the magnetic field and also be possibly applied to determine spin polarization of thermoelectric conductivity and the Seebeck coefficient of ferromagnetic thin films.</jats:p>

  29. Strain induced enhancement of perpendicular magnetic anisotropy in Co/graphene and Co/BN heterostructures 査読有り

    B. S. Yang, J. Zhang, L. N. Jiang, W. Z. Chen, P. Tang, X.-G. Zhang, Y. Yan, X. F. Han

    Physical Review B 95 (17) 2017年5月17日

    出版者・発行元: American Physical Society ({APS})

    DOI: 10.1103/physrevb.95.174424  

    ISSN:2469-9950 2469-9969

︎全件表示 ︎最初の5件までを表示

MISC 5

  1. Van der Waals bilayers: Monolayer stiffness stabilizes ferroelectricity above RT

    Ping Tang

    AIMResearch Highligh: 2025年5月

  2. Ferroelectric materials: Unveiling the “ferron” quasiparticle

    AIMResearch Highlights 2023年12月

  3. Polarization transport in ferroelectrics 招待有り 査読有り

    G.E.W. Bauer, P. Tang, R. Iguchi, J. Xiao, K. Shen, Z. Zhong, T. Yu, S.M. Rezende, J.P. Heremans, K. Uchida

    Physical Review Applied 20 (5) 2023年11月29日

    出版者・発行元: American Physical Society (APS)

    DOI: 10.1103/physrevapplied.20.050501  

    eISSN: 2331-7019

  4. Electron and magnon resonant tunneling: materials, physics and devices 招待有り 査読有り

    Xiu-Feng Han, Lingling Tao, Hao Wu, Ping Tang, Yaowen Xing

    Journal of Physics D: Applied Physics 56 (44) 443001-443001 2023年11月2日

    出版者・発行元: {IOP} Publishing

    DOI: 10.1088/1361-6463/ace72a  

    ISSN: 0022-3727 1361-6463

    eISSN: 1361-6463

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    Abstract Resonant tunneling (RT) originally refers to electron tunneling through the resonant states of double-barrier potentials with a series of sharply peaked transmission coefficients (close to unity) at certain energies. Electron RT can be used to design promising electronic devices such as RT diode. If the quantum well states are spin-dependent, the electron RT would exhibit spin-polarized or spin-selective properties, as observed in the double magnetic tunnel junctions with a thin intercalary ferromagnetic layer. As a result of the quantum wave–particle duality, RT can be further expanded to magnons—the quanta of spin waves, which opens up a new avenue of research—magnon RT. Because of the bosonic nature and macroscopic quantum coherence, the magnon RT may occur in a wide spectrum and temperature range (room temperature and above room temperature), while the electron RT typically occurs around the Fermi level and at low temperature or around room temperature. Here, we review the recent advances in RT physics of electron and magnon, and outline possible device implications.

  5. From microelectronics to spintronics and magnonics 招待有り 査読有り

    Xiu-Feng Han, Cai-Hua Wan, Hao Wu, Chen-Yang Guo, Ping Tang, Zheng-Ren Yan, Yao-Wen Xing, Wen-Qing He, Guo-Qiang Yu

    Chinese Physics B 31 (11) 117504-117504 2022年11月1日

    出版者・発行元: IOP Publishing

    DOI: 10.1088/1674-1056/ac9048  

    ISSN: 1674-1056

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    In this review, the recent developments in microelectronics, spintronics, and magnonics have been summarized and compared. Firstly, the history of the spintronics has been briefly reviewed. Moreover, the recent development of magnonics such as magnon-mediated current drag effect (MCDE), magnon valve effect (MVE), magnon junction effect (MJE), magnon blocking effect (MBE), magnon-mediated nonlocal spin Hall magnetoresistance (MNSMR), magnon-transfer torque (MTT) effect, and magnon resonant tunneling (MRT) effect, magnon skin effect (MSE), etc., existing in magnon junctions or magnon heterojunctions, have been summarized and their potential applications in memory and logic devices, etc., are prospected, from which we can see a promising future for spintronics and magnonics beyond micro-electronics.

講演・口頭発表等 16

  1. Longitudinal spin Hall magnetoresistance from spin fluctuations 招待有り

    Ping Tang

    3nd Iwate Spintronics Workshop (Morioka, Japan)

  2. Sub-terahertz surface spin waves in antiferromagnetic van der Waals multilayers 招待有り

    Ping Tang

    SpinX 2024 : Harnessing Spintronics for Tomorrow's Technology (Sendai, Japan)

  3. Electric polarization transport and “ferron” excitations in ferroelectrics 招待有り

    Ping Tang

    Topological Quantum Transport workshop (Huangshan, China)

  4. Magnonics v.s. Ferronics 招待有り

    Ping Tang

    The IEEE International Magnetics Conference (Rio de Janeiro, Brazil)

  5. Role of disorder on the orbital Hall effect 招待有り

    Ping Tang

    2nd Iwate Spintronics Workshop (Morioka, Japan)

  6. Spintronic Analog of ferroelectric materials 招待有り

    Ping Tang

    The 7th Symposium for the Core Research Clusters for Materials Science and Spintronics and the 6th Symposium on International Joint Graduate Program in Materials Science and Spintronics (Sendai, Japan)

  7. Role of impurity scatterings on the intrinsic orbital Hall effect 招待有り

    Ping Tang

    Orbitronics workshop (Daejeon, Korea)

  8. Ferrons v.s magnons

    Ping Tang

    SPICE-Workshop on Terahertz Spintronics: Toward Terahertz Spin-based Devices (Mainz, Germany)

  9. Ferron excitations in ferroelectric materials 招待有り

    Ping Tang

    Spin Summit workshop (Chengdu, China)

  10. Polarization caloritronics and ferron excitations in ferroelectrics 招待有り

    Ping Tang

    Spin Caloritronics XII (Tsukuba, Japan)

  11. Electric polarization transport and “ferron” excitations in ferroelectrics

    Ping Tang

    The IEEE International Magnetics Conference (Sendai, Japan)

  12. Polarization caloritronics and “ferron” excitations in ferroelectrics

    Ping Tang

    APS March Meeting (Las Vegas, USA)

  13. Electric polarization transport and “ferron” excitations in ferroelectrics 招待有り

    Ping Tang

    1st International Iwate Spintronics workshop (Morioka, Japan)

  14. “Ferron” excitations and polarization caloritronics in ferroelectrics

    Ping Tang

    24th International Colloquium on Magnetic Films and Surfaces (Okinawa, Japan)

  15. Ballistic polarization transport in ferroelectric point contacts

    Ping Tang

    The 82nd JSAP Autumn Meeting (online)

  16. The effect of disorder on the long-range order of 2D magnetic materials

    Ping Tang

    64th Annual Conference on Magnetism and Magnetic Materials (Las Vegas, USA)

︎全件表示 ︎最初の5件までを表示

共同研究・競争的資金等の研究課題 2

  1. Spin pumping by ferroelectric dynamics: Unveiling a novel “dynamical” magnetoelectric phenomenon

    Ping Tang

    提供機関:AIMR, Tohoku University

    研究種目:AIMR fusion project

    2024年9月 ~ 2025年3月

  2. Transport of the antiferromagnetic order

    Ping Tang

    提供機関:Japan Society for the Promotion of Science

    制度名:Grants-in-Aid for Scientific Research

    研究種目:Grant-in-Aid for Early-Career Scientists

    研究機関:Tohoku University

    2023年4月 ~ 2025年3月

担当経験のある科目(授業) 1

  1. 東北大学 スピントロニクス国際共同大学院プログラム 東北大学

学術貢献活動 1

  1. Peer Reviewer for Physical Review Letters, Physical Review B, and Applied Physics Letters

    学術貢献活動種別: 査読等