First-Principles Calculations Predict Tunable Large Magnetic Anisotropy Due to Spin-Polarized Quantum-Well Resonances in Nanometer-Thick SrRuO<sub>3</sub> Films: Implications for Spintronic Devices

Huang, Angus; Jeng, Horng Tay; Chang, Ching Hao

doi:10.1021/acsanm.1c00775

Cited by 6 publications

(2 citation statements)

References 71 publications

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“…Specific to SIO, we demonstrate the cause of MIT and report the possible existence of multiple Dirac states. Irrespective of layer termination, we show that, these ultrathin films exhibits large MAE which is one to two order higher than the traditional MAE materials like transition metals and their multilayers [26][27][28] .…”

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confidence: 84%

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Induction of Large Magnetic Anisotropy Energy and Formation of Multiple Dirac States in SrIrO$_3$ Films: Role of correlation and spin-orbit coupling

Chauhan,

Nanda

2021

Preprint

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confidence: 84%

“…It is very rare that oxide films possess large MAE. A very recent theoretical study on SrRuO 3 thin films report a MAE of ≈ 0.62 meV/Ru26 . Also, for comparison, the MAE for other known oxides is summarized in Table-I.…”

mentioning

confidence: 96%

Induction of Large Magnetic Anisotropy Energy and Formation of Multiple Dirac States in SrIrO$_3$ Films: Role of correlation and spin-orbit coupling

Chauhan,

Nanda

2021

Preprint

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Flexoelectric polarizing and control of a ferromagnetic metal

Peng,

Park,

Roh

et al. 2024

Nat. Phys.

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Electric polarization is well defined only in insulators not metals, and there is no general scheme to induce and control bulk polarity in metals. Here we circumvent this limitation by utilizing a pseudo-electric field generated by inhomogeneous lattice strain, namely a flexoelectric field, as a means of polarizing and controlling a metal. Using heteroepitaxy and atomic-scale imaging, we show that flexoelectric fields polarize the bulk of an otherwise centrosymmetric metal SrRuO3, with off-centre displacements of Ru ions. This further impacts the electronic bands and lattice anisotropy of the flexo-polar SrRuO3, potentially leading to an enhancement of electron correlation, ferromagnetism and its anisotropy. Beyond conventional electric fields, flexoelectric fields may be used to create and control electronic states through pure atomic displacements.

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Challenges in identifying chiral spin textures via the topological Hall effect

Kimbell

Kim

et al. 2022

Commun Mater

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Chiral spin textures such as skyrmions are of interest to the field of spintronics for their potential use in future computing devices. Hall effect measurements are a simple and powerful method to probe the electronic and magnetic properties of materials. The topological Hall effect, which appears as anomalies in Hall resistance versus magnetic field measurements compared to magnetic measurements, has frequently been used to establish the occurrence of chiral spin textures. However, in addition to experimental issues, intrinsic electronic mechanisms combined with inhomogeneity in materials and at interfaces can lead to an inhomogeneous anomalous Hall effect which could be mistaken for a topological Hall signal. This review covers recent research using Hall effect measurements to probe chiral spin textures, focusing on SrRuO3 as a model system. The ambiguity between Hall effects due to topological sources has led to disagreement in the interpretation of experimental results and casts doubts on the effectiveness of these techniques for investigating chiral spin textures.

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First-Principles Calculations Predict Tunable Large Magnetic Anisotropy Due to Spin-Polarized Quantum-Well Resonances in Nanometer-Thick SrRuO₃ Films: Implications for Spintronic Devices

Cited by 6 publications

References 71 publications

Induction of Large Magnetic Anisotropy Energy and Formation of Multiple Dirac States in SrIrO$_3$ Films: Role of correlation and spin-orbit coupling

Induction of Large Magnetic Anisotropy Energy and Formation of Multiple Dirac States in SrIrO$_3$ Films: Role of correlation and spin-orbit coupling

Flexoelectric polarizing and control of a ferromagnetic metal

Challenges in identifying chiral spin textures via the topological Hall effect

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First-Principles Calculations Predict Tunable Large Magnetic Anisotropy Due to Spin-Polarized Quantum-Well Resonances in Nanometer-Thick SrRuO3 Films: Implications for Spintronic Devices

Cited by 6 publications

References 71 publications

Induction of Large Magnetic Anisotropy Energy and Formation of Multiple Dirac States in SrIrO$_3$ Films: Role of correlation and spin-orbit coupling

Induction of Large Magnetic Anisotropy Energy and Formation of Multiple Dirac States in SrIrO$_3$ Films: Role of correlation and spin-orbit coupling

Flexoelectric polarizing and control of a ferromagnetic metal

Challenges in identifying chiral spin textures via the topological Hall effect

Contact Info

Product

Resources

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First-Principles Calculations Predict Tunable Large Magnetic Anisotropy Due to Spin-Polarized Quantum-Well Resonances in Nanometer-Thick SrRuO₃ Films: Implications for Spintronic Devices