Manipulation of competing ferromagnetic and antiferromagnetic domains in exchange-biased nanostructures

Rodríguez, A. Fraile; Basaran, Ali C.; Morales, R.; Kovylina, Miroslavna; Llobet, Jordi; Borrisé, Xavier; Marcus, Matthew A.; Schöll, A.; Schuller, Iván K.; Batlle, X.; Labarta, A.

doi:10.1103/physrevb.92.174417

Cited by 10 publications

(7 citation statements)

References 45 publications

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“…Besides, PEEM in this case is sensitive to the additional PUM present on the side-walls of the antidots. These measurements proved that in antidot containing samples additional PEB domains appear, when the Zeeman energy of bulk PUM locally overcome the exchange energy at the FM/AFM interface [34]. Independent PEEM experiments also suggested the presence of additional bulk PUM on the artificially-created, exposed lateral AFM walls as a result of the antidot carving [34].…”

Section: Artificial Bulk Pummentioning

confidence: 86%

Role of the antiferromagnetic bulk spins in exchange bias

Schuller

Morales

Batlle

et al. 2016

Journal of Magnetism and Magnetic Materials

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a b s t r a c tThis "Critical Focused Issue" presents a brief review of experiments and models which describe the origin of exchange bias in epitaxial or textured ferromagnetic/antiferromagnetic bilayers. Evidence is presented which clearly indicates that inner, uncompensated, pinned moments in the bulk of the antiferromagnet (AFM) play a very important role in setting the magnitude of the exchange bias. A critical evaluation of the extensive literature in the field indicates that it is useful to think of this bulk, pinned uncompensated moments as a new type of a ferromagnet which has a low total moment, an ordering temperature given by the AFM Néel temperature, with parallel aligned moments randomly distributed on the regular AFM lattice.

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Section: Artificial Bulk Pummentioning

confidence: 86%

Role of the antiferromagnetic bulk spins in exchange bias

Schuller

Morales

Batlle

et al. 2016

Journal of Magnetism and Magnetic Materials

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“…We assume that the domains in the AFM, which are due to the energy balance and that originate EB, are created during field cooling and remain frozen even when the FM is fully saturated, as observed experimentally in exchange coupled bilayers. 24,[30][31][32][33] As shown in Fig. 2(a), during the field cooling process FM layers are fully saturated and magnetic domains are nucleated at AFM, simultaneously.…”

Section: Theoretical Modelmentioning

confidence: 98%

“…Our assumption about AFM domains is based on photoemission, electron microscopy and X-ray magnetic circular dichroism measurements, 30,34 by the formation of a two domain state, composed of uncompensated spins, as observed experimentally. 14,35,36 Since for large cooling fields the anisotropy energy is significantly larger than the dipolar and Zeeman energies, these domains remain frozen during the hysteresis cycle.…”

Section: Theoretical Modelmentioning

confidence: 99%

“…When the field is swept during the hysteresis cycle the magnetic domain formation on the FM is determined by the competition between the formation of large domains induced by the Zeeman interaction and the formation of small domains due to the local dipole fields. 30 The FM-AFM interaction energy density of two noninteracting FM domains is given by…”

Section: Theoretical Modelmentioning

confidence: 99%

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Dipole-induced exchange bias

et al. 2017

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The discovery of dipole-induced exchange bias (EB), switching from negative to positive sign, is reported in systems where the antiferromagnet and the ferromagnet are separated by a paramagnetic spacer (AFM-PM-FM). The magnitude and sign of the EB is determined by the cooling field strength and the PM thickness. The same cooling field yields negative EB for thin spacers, and positive EB for thicker ones. The EB decay profile as a function of the spacer thickness, and the change of sign, are attributed to long-ranged dipole coupling. Our model, which accounts quantitatively for the experimental results, ignores the short range interfacial exchange interactions of the usual EB theories. Instead, it retains solely the long range dipole field that allows for the coupling of the FM and AFM across the PM spacer. The experiments allow for novel switching capabilities of long range EB systems, while the theory allows description of the structures where the FM and AFM are not in atomic contact. The results provide a new approach to design novel interacting heterostructures.

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“…a single-domain approximation) [37]. (ii) The antiferromagnetic uncompensated magnetization in the vicinity of ferromagnet/antiferromagnet interface exists due to D IF and H FC [26,38], also based on the photoemission, electron microscopy, and x-ray magnetic circular dichroism measurements experimentally [39][40][41][42][43]. (iii) There are longrange dipolar interactions between ferromagnetic and antiferromagnetic domains.…”

Section: Theorymentioning

confidence: 99%

Cooling-field dependence of dipole-induced loop bias

Lü²,

Chi³

et al. 2019

Nanotechnology

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In ferromagnet/antiferromagnet bilayers and core/shell nanoparticles, an exchange-bias-like loop bias phenomenon in the ferromagnet is observed solely due to the long-range dipolar interactions between ferromagnet and antiferromagnet. With increasing cooling field, the loop bias field may increase from zero in the bilayers or from a negative value in the core/shell nanoparticles to a positive saturated value, depending on the interfacial dipolar interaction and/or ferromagnetic/antiferromagnetic thickness. Using a modified Monte-Carlo method and the Meiklejohn–Bean model, the interfacial dipole fields (up to several teslas) and the domain sizes imprinted on the interfacial antiferromagnet are explicitly calculated to elucidate the cooling field dependence of loop bias, which is governed by distinct mechanisms at the flat and curved interfaces. Finally, through simply discussing the roles of lattice structure, ferromagnetic dipolar interaction, and simulation time, it is evidenced that the dipole-induced loop bias is ubiquitous and applicable for stabilizing a ferromagnet, irrespective of the interface mismatch and the undeterministic diffusion between different ingredients. This work helps us to develop the spintronic devices with nonatomic-contact nanostructure assemblies.

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Manipulation of competing ferromagnetic and antiferromagnetic domains in exchange-biased nanostructures

Cited by 10 publications

References 45 publications

Role of the antiferromagnetic bulk spins in exchange bias

Role of the antiferromagnetic bulk spins in exchange bias

Dipole-induced exchange bias

Cooling-field dependence of dipole-induced loop bias

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