Dzyaloshinskii-Moriya Torque-Driven Resonance in Antiferromagnetic & alpha;-Fe2O3

Article Chemistry, Multidisciplinary

Topological Spin Textures in a Non-Collinear Antiferromagnet System

Xionghua Liu et al.

Summary: Researchers have reported a method to realize room-temperature skyrmions in natural metallic antiferromagnetic materials, which have potential for convenient electrical manipulation, attracting extensive interest recently.

ADVANCED MATERIALS (2023)

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Article Physics, Applied

Antiferromagnetic resonance in a-Fe2O3 up to its Neel temperature

M. Bialek et al.

Summary: This study characterizes the antiferromagnetic resonance of hematite and estimates its Neel temperature to be 966 K.

APPLIED PHYSICS LETTERS (2022)

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Article Chemistry, Multidisciplinary

Observation of Standing Spin Waves in a van der Waals Magnetic Material

Lucky N. Kapoor et al.

Summary: Researches on spin waves for data storage, communication, and logic circuits in the field of spintronics are gaining renewed interest due to recent discovery of magnetism in 2D systems; Direct evidence of standing spin waves and uniform precessional resonance modes were presented in van der Waals magnetic material, CrCl3; Detection of standing spin waves near both branches, optical and acoustic, of antiferromagnetic resonance suggests potential for extraction of interlayer exchange field with temperature.

ADVANCED MATERIALS (2021)

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Article Multidisciplinary Sciences

Reversible hydrogen control of antiferromagnetic anisotropy in α-Fe2O3

Hariom Jani et al.

Summary: Researchers demonstrate the reversible ionic control of the magnetic anisotropy and spin reorientation transition in hematite by incorporating and removing hydrogen, providing insights for future applications in antiferromagnetic spintronics.

NATURE COMMUNICATIONS (2021)

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Article Physics, Multidisciplinary

Room-Temperature Antiferromagnetic Resonance and Inverse Spin-Hall Voltage in Canted Antiferromagnets

I Boventer et al.

Summary: The study demonstrates that spin pumping signals induced by the resonance of canted antiferromagnets with Dzyaloshinskii-Moriya interaction can generate easily observable inverse spin-Hall voltages. Using a bilayer of hematite/heavy metal as a model system, the research shows that antiferromagnetic resonance and associated inverse spin-Hall voltages can be measured at room temperature. Direct information about the mode handedness can be obtained by comparing different materials.

PHYSICAL REVIEW LETTERS (2021)

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Article Physics, Applied

Strong Coupling of Antiferromagnetic Resonance with Subterahertz Cavity Fields

M. Bialek et al.

Summary: The study demonstrates strong coupling between electromagnetic cavity fields and antiferromagnetic spin waves in hematite above room temperature. Spectra collected as a function of temperature reveal the formation of magnetic polaritons.

PHYSICAL REVIEW APPLIED (2021)

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Article Physics, Applied

Control of antiferromagnetic resonance and the Morin temperature in cation doped α-Fe2-xMxO3 (M = Al, Ru, Rh, and In)

Kensuke Hayashi et al.

Summary: This study investigates the tunability of resonant frequency in alpha-Fe2O3 through cation doping, showing potential for applications in millimeter-wave and THz bands. The mechanism of Morin temperature shift upon cation doping is discussed, indicating the usefulness of cation doped alpha-Fe2O3 for THz applications.

APPLIED PHYSICS LETTERS (2021)

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Article Physics, Multidisciplinary

Spin Pumping of an Easy-Plane Antiferromagnet Enhanced by Dzyaloshinskii-Moriya Interaction

Hailong Wang et al.

Summary: This study reports dc spin pumping by the acoustic resonant mode in a canted easy-plane antiferromagnet alpha-Fe2O3. The observed spin-pumping signals in alpha-Fe2O3-metal heterostructures are attributed to resonance-induced spin injection and inverse spin Hall effect, revealing intriguing physics underlying the low-frequency spin dynamics and transport in these structures.

PHYSICAL REVIEW LETTERS (2021)

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Article Materials Science, Multidisciplinary

Excitation and detection of terahertz coherent spin waves in antiferromagnetic α-Fe2O3

K. Grishunin et al.

Summary: Efficiency of ultrafast spin excitation in antiferromagnetic alpha-Fe2O3 using a nearly single-cycle THz pulse is studied with respect to THz pulse polarization and sample temperature. Above the Morin point, most effective excitation occurs when the magnetic field of the THz pulse is perpendicular to the antiferromagnetically coupled spins. The mechanism of spin excitation above and below the Morin point relies on a magnetic-dipole interaction of the THz magnetic field with spins, where coupling efficiency is proportional to the time derivative of the magnetic field.

PHYSICAL REVIEW B (2021)

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Article Multidisciplinary Sciences