Exchange bias in Fe/Ir20Mn80 bilayers: Role of spin-glass like interface and ‘bulk’ antiferromagnet spins

Nayak, Sagarika; Manna, P. K.; Thiruvengadam, V.; Singh, Braj Bhusan; Chelvane, J. Arout

doi:10.1016/j.jmmm.2019.166267

Cited by 9 publications

(2 citation statements)

References 41 publications

(58 reference statements)

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“…In figure 2, in the case of ZFC measurements, H c monotonically increases with decreasing temperature with an increase in H ex below T EB of ∼50 K in CoPc devices and 30 K in the case of MnPc devices. Here, based on our understanding of FM/AFM [19,37,38] or FM/spin-glass exchange-bias system [29], the enhancement in H c relative to the reference-Fe can be understood to arise from two additive but competing effects -surface exchange induced magnetic anisotropy (K i ex ) in the bottom Fe layer and softer domains or frustrated spin centers in the hard surface layer matrix that couple with the bottom Fe layer and partially rotate upon magnetization reversal. Generally, the latter effect depends on interface-disorder and spin-frustration and its strong presence leads to a drop in H c at lower temperatures caused by surface domain freezing, whereby they stop contributing to the H c enhancement [19,29,39].…”

Section: Resultsmentioning

confidence: 99%

Evidence of Spin-Glass state in Molecular Exchange-Bias System

Mundlia,

Raman

2020

Preprint

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In conventional exchange-bias system comprising of a bilayer film of ferromagnet (FM) and antiferromagnet (AFM), investigating the role of spin-disorder and spin-frustration inside the AFM and at the interface has been crucial in understanding the fundamental mechanism controlling the exchange-bias -an effect that leads to a horizontal shift in the magnetization hysteresis response of the FM. Similarly, in the recently reported monolayer molecular exchange-bias effect requiring no AFM layer, probing magnetic-disorder at the FM/molecule interface or inside the FM layer can provide new insights into the origin of molecular exchange-bias and the associated physics. In this article, by cooling the Fe/metal-phthalocyanine devices in oscillating magnetic field, we demonstrate a characteristic temperature dependent response of exchange-bias shift and ferromagnet coercivity that is supportive of a spin-glass behavior. Here, the origin of spin-glass is attributed to the spinfrustration created in the magnetic structure of the Fe layer, which was absent in our reference-Fe studies. These results highlight the strong influence of FM/molecule interface π − d hybridization on the magnetic exchange interactions extending deeper into the FM layer.

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Section: Resultsmentioning

confidence: 99%

Evidence of Spin-Glass state in Molecular Exchange-Bias System

Mundlia,

Raman

2020

Preprint

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“…Despite intensive experimental research in the field, there are phenomena like spontaneous EB [17], EB in alloys and compounds [18,19], EB in single phase magnetically inhomogeneous materials [20] or EB in thin films [21,22] that are still drawing attention because of the urge to understand new fundamental physics. Furthermore, EB reveals a wide range of potential applications in recording media to overcome the superparamagnetic (SPM) limit [23], field sensors [24], read heads [25], giant magnetoresistance (GMR) based devices [26] and many more as well.…”

Section: Introductionmentioning

confidence: 99%

Dependence of Exchange Bias on Interparticle Interactions in Co/CoO Core/Shell Nanostructures

Goswami¹,

Gupta

Nayak

et al. 2022

Nanomaterials

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This article reports the dependence of exchange bias (EB) effect on interparticle interactions in nanocrystalline Co/CoO core/shell structures, synthesized using the conventional sol-gel technique. Analysis via powder X-Ray diffraction (PXRD) studies and transmission electron microscope (TEM) images confirm the presence of crystalline phases of core/shell Co/CoO with average particle size ≈ 18 nm. Volume fraction (φ) is varied (from 20% to 1%) by the introduction of a stoichiometric amount of non-magnetic amorphous silica matrix (SiO2) which leads to a change in interparticle interaction (separation). The influence of exchange and dipolar interactions on the EB effect, caused by the variation in interparticle interaction (separation) is studied for a series of Co/CoO core/shell nanoparticle systems. Studies of thermal variation of magnetization (M−T) and magnetic hysteresis loops (M−H) for the series point towards strong dependence of magnetic properties on dipolar interaction in concentrated assemblies whereas individual nanoparticle response is dominant in isolated nanoparticle systems. The analysis of the EB effect reveals a monotonic increase of coercivity (HC) and EB field (HE) with increasing volume fraction. When the nanoparticles are close enough and the interparticle interaction is significant, collective behavior leads to an increase in the effective antiferromagnetic (AFM) CoO shell thickness which results in high HC and HE. Moreover, in concentrated assemblies, the dipolar field superposes to the local exchange field and enhances the EB effect contributing as an additional source of unidirectional anisotropy.

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Magnetization and Magnetic Microscopy Studies in Fe Thin Films

Jeyaramane

Prasad

2021

Journal of Elec Materi

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Exchange bias in Fe/Ir20Mn80 bilayers: Role of spin-glass like interface and ‘bulk’ antiferromagnet spins

Cited by 9 publications

References 41 publications

Evidence of Spin-Glass state in Molecular Exchange-Bias System

Evidence of Spin-Glass state in Molecular Exchange-Bias System

Dependence of Exchange Bias on Interparticle Interactions in Co/CoO Core/Shell Nanostructures

Magnetization and Magnetic Microscopy Studies in Fe Thin Films

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