Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices
The ability to tune magnetic orders, such as magnetic anisotropy and topological spin texture, is desired to achieve high-performance spintronic devices. A recent strategy has been to employ interfacial engineering techniques, such as the introduction of spin-correlated interfacial coupling, to tail...
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2021
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Science::Physics Calculations Electrons Huang, Ke Wu, Liang Wang, Maoyu Swain, Nyayabanta Motapothula, M. Luo, Yongzheng Han, Kun Chen, Mingfeng Ye, Chen Yang, Allen Jian Xu, Huan Qi, Dong-chen N'Diaye, Alpha T. Panagopoulos, Christos Primetzhofer, Daniel Shen, Lei Sengupta, Pinaki Ma, Jing Feng, Zhenxing Nan, Ce-Wen Wang, Renshaw Xiao Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
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The ability to tune magnetic orders, such as magnetic anisotropy and topological spin texture, is desired to achieve high-performance spintronic devices. A recent strategy has been to employ interfacial engineering techniques, such as the introduction of spin-correlated interfacial coupling, to tailor magnetic orders and achieve novel magnetic properties. We chose a unique polar–nonpolar LaMnO3/SrIrO3 superlattice because Mn (3d)/Ir (5d) oxides exhibit rich magnetic behaviors and strong spin–orbit coupling through the entanglement of their 3d and 5d electrons. Through magnetization and magnetotransport measurements, we found that the magnetic order is interface-dominated as the superlattice period is decreased. We were able to then effectively modify the magnetization, tilt of the ferromagnetic easy axis, and symmetry transition of the anisotropic magnetoresistance of the LaMnO3/SrIrO3 superlattice by introducing additional Mn (3d) and Ir (5d) interfaces. Further investigations using in-depth first-principles calculations and numerical simulations revealed that these magnetic behaviors could be understood by the 3d/5d electron correlation and Rashba spin–orbit coupling. The results reported here demonstrate a new route to synchronously engineer magnetic properties through the atomic stacking of different electrons, which would contribute to future applications in high-capacity storage devices and advanced computing. |
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School of Physical and Mathematical Sciences |
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School of Physical and Mathematical Sciences Huang, Ke Wu, Liang Wang, Maoyu Swain, Nyayabanta Motapothula, M. Luo, Yongzheng Han, Kun Chen, Mingfeng Ye, Chen Yang, Allen Jian Xu, Huan Qi, Dong-chen N'Diaye, Alpha T. Panagopoulos, Christos Primetzhofer, Daniel Shen, Lei Sengupta, Pinaki Ma, Jing Feng, Zhenxing Nan, Ce-Wen Wang, Renshaw Xiao |
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Article |
| author |
Huang, Ke Wu, Liang Wang, Maoyu Swain, Nyayabanta Motapothula, M. Luo, Yongzheng Han, Kun Chen, Mingfeng Ye, Chen Yang, Allen Jian Xu, Huan Qi, Dong-chen N'Diaye, Alpha T. Panagopoulos, Christos Primetzhofer, Daniel Shen, Lei Sengupta, Pinaki Ma, Jing Feng, Zhenxing Nan, Ce-Wen Wang, Renshaw Xiao |
| author_sort |
Huang, Ke |
| title |
Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
| title_short |
Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
| title_full |
Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
| title_fullStr |
Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
| title_full_unstemmed |
Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
| title_sort |
tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices |
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2021 |
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https://hdl.handle.net/10356/148735 |
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1759853501152755712 |
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sg-ntu-dr.10356-1487352023-02-28T19:57:22Z Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices Huang, Ke Wu, Liang Wang, Maoyu Swain, Nyayabanta Motapothula, M. Luo, Yongzheng Han, Kun Chen, Mingfeng Ye, Chen Yang, Allen Jian Xu, Huan Qi, Dong-chen N'Diaye, Alpha T. Panagopoulos, Christos Primetzhofer, Daniel Shen, Lei Sengupta, Pinaki Ma, Jing Feng, Zhenxing Nan, Ce-Wen Wang, Renshaw Xiao School of Physical and Mathematical Sciences School of Electrical and Electronic Engineering Science::Physics Calculations Electrons The ability to tune magnetic orders, such as magnetic anisotropy and topological spin texture, is desired to achieve high-performance spintronic devices. A recent strategy has been to employ interfacial engineering techniques, such as the introduction of spin-correlated interfacial coupling, to tailor magnetic orders and achieve novel magnetic properties. We chose a unique polar–nonpolar LaMnO3/SrIrO3 superlattice because Mn (3d)/Ir (5d) oxides exhibit rich magnetic behaviors and strong spin–orbit coupling through the entanglement of their 3d and 5d electrons. Through magnetization and magnetotransport measurements, we found that the magnetic order is interface-dominated as the superlattice period is decreased. We were able to then effectively modify the magnetization, tilt of the ferromagnetic easy axis, and symmetry transition of the anisotropic magnetoresistance of the LaMnO3/SrIrO3 superlattice by introducing additional Mn (3d) and Ir (5d) interfaces. Further investigations using in-depth first-principles calculations and numerical simulations revealed that these magnetic behaviors could be understood by the 3d/5d electron correlation and Rashba spin–orbit coupling. The results reported here demonstrate a new route to synchronously engineer magnetic properties through the atomic stacking of different electrons, which would contribute to future applications in high-capacity storage devices and advanced computing. Ministry of Education (MOE) Nanyang Technological University National Research Foundation (NRF) Published version X.R.W. acknowledges support from the Nanyang Assistant Professorship grant from Nanyang Technological University and Academic Research Fund Tier 1 (Grant Nos. RG108/17 and RG177/18) and Tier 3 (Grant No. MOE2018-T3-1-002) from the Singapore Ministry of Education. L.S. acknowledges support from Singapore MOE Tier 1 (Grant No. R-265-000-615-114). N.S. and P.S. acknowledge the support of Grant No. MOE2014-T2-2-112 from the Ministry of Education, Singapore, and the computational resources of the NSCC ASPIRE1 cluster in Singapore. D.Q. acknowledges the support of the Australian Research Council (Grant No. FT160100207). C.P. acknowledges financial support from the Academic Research Fund Tier 3 (Reference No. MOE5093) and the National Research Foundation (Reference No. NRF-NRFI2015-04). C.W.N. acknowledges support from the Basic Science Center Program of NSFC (Grant No. 51788104). Part of this research was undertaken on the soft X-ray spectroscopy beamline at the Australian Synchrotron, part of ANSTO, and the rest of the soft X-ray spectroscopy measurements were performed at beamline 6.3.1 of Advanced Light Source, which is an Office of Science User Facility operated for the U.S. DOE Office of Science by Lawrence Berkeley National Laboratory and supported by the DOE under Contract No. DEAC02-05CH11231. 2021-05-17T07:22:27Z 2021-05-17T07:22:27Z 2020 Journal Article Huang, K., Wu, L., Wang, M., Swain, N., Motapothula, M., Luo, Y., Han, K., Chen, M., Ye, C., Yang, A. J., Xu, H., Qi, D., N'Diaye, A. T., Panagopoulos, C., Primetzhofer, D., Shen, L., Sengupta, P., Ma, J., Feng, Z., ...Wang, R. X. (2020). Tailoring magnetic order via atomically stacking 3d/5d electrons to achieve high-performance spintronic devices. Applied Physics Reviews, 7(1). https://dx.doi.org/10.1063/1.5124373 1931-9401 0000-0003-1030-6997 0000-0002-3706-0598 0000-0002-5142-2508 0000-0001-8408-0359 0000-0001-8466-0257 0000-0001-9429-9776 0000-0002-5815-3742 0000-0001-6198-5753 0000-0003-0103-9858 0000-0001-7598-5076 0000-0002-5503-9899 https://hdl.handle.net/10356/148735 10.1063/1.5124373 2-s2.0-85077514352 1 7 en RG108/17 RG177/18 MOE2018-T3-1-002 R-265-000-615-114 MOE2014-T2-2-112 MOE5093 NRF-NRFI2015-04 Applied Physics Reviews © 2020 The Author(s). All rights reserved. This paper was published by American Institute of Physics (AIP) in Applied Physics Reviews and is made available with permission of The Author(s). application/pdf |