Coupling of pinned magnetic moments in an antiferromagnet to a ferromagnet and its role for exchange bias

Khan, Muhammad Yaqoob; Shokr, Yasser A.; Kuch, W.

doi:10.1088/1361-648x/ab531a

Cited by 4 publications

(2 citation statements)

References 31 publications

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“…Exchange bias originates from uncompensated pinned magnetic moments within the AFM, which couple to the FM layer. Since these pinned magnetic moments are distributed throughout the AFM layer, [23,[37][38][39][40][41] their coupling to the FM layer and thus the exchange-bias field depends on the intra-AFM exchange interaction. A smaller average vertical atomic spacing enhances the exchange interaction in the AFM layer.…”

Section: Resultsmentioning

confidence: 99%

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu₃Au(001)

Shinwari

Gelen

Villanueva

et al. 2023

Physica Status Solidi (b)

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Single‐crystalline antiferromagnetic artificially layered [Ni/Mn] films of different thicknesses, covered by ferromagnetic Co layers, are deposited on . Their structural and magnetic properties are characterized by low‐energy electron diffraction (LEED) and magneto‐optical Kerr effect, respectively, and compared with disordered alloy films with the same Ni/Mn ratio and the same film thickness. LEED intensity‐versus‐energy curves show that the perpendicular interatomic lattice distance is decreased in the artificially layered [Ni/Mn] samples in comparison to the disordered alloy films. At the same time, the artificially layered [Ni/Mn] films exhibit higher coercivity and exchange bias of the adjacent Co layer compared to those of . This is discussed as a consequence of the different interatomic lattice distance, presumably caused by an ordered buckling in the artificially layered [Ni/Mn] samples, leading to a stronger interlayer exchange coupling.

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Section: Resultsmentioning

confidence: 99%

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu₃Au(001)

Shinwari

Gelen

Villanueva

et al. 2023

Physica Status Solidi (b)

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“…As previous reported, the EB effect in some Heusler alloys can be attributed to the exchange coupling between the SG and the AFM matrix, since the short-range ordered FM clusters are assumed to be formed in the SG state during application of an external field in the cooling process. 29) Recently, it was found that H EB depends strongly on the size of the FM clusters in the AFM matrix. 30) The size of the FM clusters in the SG and SSG systems are different at varying temperatures under ZFC and FC processes, resulting in a huge difference in the EB effect.…”

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Tuning the exchange bias effect via thermal treatment temperature in bulk Ni₅₀Mn₄₂In₃Sb₅ Heusler alloys

Cao

Tian

Huang³

et al. 2021

Appl. Phys. Express

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An interesting evolution of spin glass behaviors and the corresponding exchange bias effects were observed by quenching Ni50Mn42In3Sb5 Heusler alloys at different temperatures. When the alloy is quenched at 1173 K, it will freeze from antiferromagnetic to spin glass at low temperature under an external magnetic field, creating a giant exchange bias field up to 9063 Oe through the pinning effect. In another case, the superparamagnetic in alloys quenched at 473 K will transform to superspin glass after zero-field cooling at low temperatures instead. As a result, a spontaneous exchange bias effect up to 581 Oe can be achieved.

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Bulk and Interfacial Effects in the Co/NixMn100−x Exchange‐Bias System due to Creation of Defects by Ar+ Sputtering

Shinwari

Gelen

Shokr

et al. 2021

Physica Rapid Research Ltrs

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Research on ultrathin magnetic layers and layered materials has reached an enormous impact, both scientifically and economically, with respect to applications in magnetic data storage technology, as sensors, or for future electronics utilizing the spin rather than the charge of electrons, the so-called "spintronics". [1][2][3][4] The physical size of a bit of information in magnetic data storage is already in the nanometer regime and is still shrinking, following the everincreasing demand for higher recording densities. Very soon the dimension of the recording bit will reach the sub-10 nm range. This poses formidable challenges to the read sensors. One ingredient of hard disk read sensors are magnetic layered systems in which ferromagnetic (FM) and antiferromagnetic (AFM) materials are in contact. [5] They show the exchange bias (EB) effect, which has received increased attention during the past decades. [6][7][8][9][10][11] It manifests itself in a shift of the magnetic hysteresis loop of the FM layer along the field axis. [12] Although reported first in 1956, [13] it was only in the mid-1990s that it shifted into the center of interest, triggered by applications of FM/AFM heterostructures for tailoring the magnetic properties of magnetoresistive devices. The past years have seen significant advances toward an explanation of the effect, however, a fundamental microscopic picture of the origin of the unidirectional magnetic anisotropy present in the EB effect is still missing.The occurrence of EB requires two basic ingredients: a magnetic interaction between FM and AFM spins at the interface, and a pinning of magnetic moments against the reversal of the FM-layer magnetization by the external magnetic field inside the AFM layer. As in AFM materials the direction of the spins varies on the length scale of single atomic distances, a thorough characterization of the atomic structure of the films and their interface is mandatory for fundamental investigations into the effect. In the commonly used polycrystalline systems prepared by sputtering techniques this is naturally not the case. A promising approach is the investigation of single-crystalline systems. [14][15][16][17][18][19] In such systems, it is shown, for example, that the magnetic coupling between AFM and FM layers is due to

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Coupling of pinned magnetic moments in an antiferromagnet to a ferromagnet and its role for exchange bias

Cited by 4 publications

References 31 publications

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu₃Au(001)

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu₃Au(001)

Tuning the exchange bias effect via thermal treatment temperature in bulk Ni₅₀Mn₄₂In₃Sb₅ Heusler alloys

Bulk and Interfacial Effects in the Co/NixMn100−x Exchange‐Bias System due to Creation of Defects by Ar+ Sputtering

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Coupling of pinned magnetic moments in an antiferromagnet to a ferromagnet and its role for exchange bias

Cited by 4 publications

References 31 publications

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu3Au(001)

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu3Au(001)

Tuning the exchange bias effect via thermal treatment temperature in bulk Ni50Mn42In3Sb5 Heusler alloys

Bulk and Interfacial Effects in the Co/NixMn100−x Exchange‐Bias System due to Creation of Defects by Ar+ Sputtering

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Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu₃Au(001)

Growth, Structure, and Magnetic Properties of Artificially Layered NiMn in Contact to Ferromagnetic Co on Cu₃Au(001)

Tuning the exchange bias effect via thermal treatment temperature in bulk Ni₅₀Mn₄₂In₃Sb₅ Heusler alloys