Chirality Memory Stored in Magnetic Domain Walls in the Ferromagnetic State of MnP

N. Jiang; Y. Nii; H. Arisawa; E. Saitoh; J. Ohe; Y. Onose

doi:10.1103/PhysRevLett.126.177205

Chirality Memory Stored in Magnetic Domain Walls in the Ferromagnetic State of MnP

N. Jiang, Y. Nii, H. Arisawa, E. Saitoh, J. Ohe, Y. Onose

IMR - Materials Design Division

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

Chirality in a helimagnetic structure is determined by the sense of magnetic moment rotation. We found that the chiral information did not disappear even after the phase transition to the high-temperature ferromagnetic phase in a helimagnet MnP. The 2nd harmonic resistivity ρ2f, which reflects the breaking down of mirror symmetry, was found to be almost unchanged after heating the sample above the ferromagnetic transition temperature and cooling it back to the helimagnetic state. The application of a magnetic field along the easy axis in the ferromagnetic state quenched the chirality-induced ρ2f. This indicates that the chirality memory effect originated from the ferromagnetic domain walls.

Original language	English
Article number	177205
Journal	Physical Review Letters
Volume	126
Issue number	17
DOIs	https://doi.org/10.1103/PhysRevLett.126.177205
Publication status	Published - 2021 Apr 28

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10.1103/PhysRevLett.126.177205

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abstract = "Chirality in a helimagnetic structure is determined by the sense of magnetic moment rotation. We found that the chiral information did not disappear even after the phase transition to the high-temperature ferromagnetic phase in a helimagnet MnP. The 2nd harmonic resistivity ρ2f, which reflects the breaking down of mirror symmetry, was found to be almost unchanged after heating the sample above the ferromagnetic transition temperature and cooling it back to the helimagnetic state. The application of a magnetic field along the easy axis in the ferromagnetic state quenched the chirality-induced ρ2f. This indicates that the chirality memory effect originated from the ferromagnetic domain walls.",

author = "N. Jiang and Y. Nii and H. Arisawa and E. Saitoh and J. Ohe and Y. Onose",

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AU - Jiang, N.

AU - Nii, Y.

AU - Arisawa, H.

AU - Saitoh, E.

AU - Ohe, J.

AU - Onose, Y.

PY - 2021/4/28

Y1 - 2021/4/28

N2 - Chirality in a helimagnetic structure is determined by the sense of magnetic moment rotation. We found that the chiral information did not disappear even after the phase transition to the high-temperature ferromagnetic phase in a helimagnet MnP. The 2nd harmonic resistivity ρ2f, which reflects the breaking down of mirror symmetry, was found to be almost unchanged after heating the sample above the ferromagnetic transition temperature and cooling it back to the helimagnetic state. The application of a magnetic field along the easy axis in the ferromagnetic state quenched the chirality-induced ρ2f. This indicates that the chirality memory effect originated from the ferromagnetic domain walls.

AB - Chirality in a helimagnetic structure is determined by the sense of magnetic moment rotation. We found that the chiral information did not disappear even after the phase transition to the high-temperature ferromagnetic phase in a helimagnet MnP. The 2nd harmonic resistivity ρ2f, which reflects the breaking down of mirror symmetry, was found to be almost unchanged after heating the sample above the ferromagnetic transition temperature and cooling it back to the helimagnetic state. The application of a magnetic field along the easy axis in the ferromagnetic state quenched the chirality-induced ρ2f. This indicates that the chirality memory effect originated from the ferromagnetic domain walls.

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Chirality Memory Stored in Magnetic Domain Walls in the Ferromagnetic State of MnP

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