Highly Tunable Magnetic and Magnetotransport Properties of Exchange Coupled Ferromagnet/Antiferromagnet-Based Heterostructures

Arekapudi, Sri Sai Phani Kanth; Bülz, Daniel; Ganss, Fabian; Samad, Fabian; Luo, Chen; Zahn, Dietrich R. T.; Lenz, K.; Salvan, Georgeta; Albrecht, Manfred; Hellwig, Olav

doi:10.1021/acsami.1c18017

Cited by 3 publications

(3 citation statements)

References 71 publications

(205 reference statements)

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“…In contrast to conventional intrinsic systems, the exchange bias in the SAF-based system is not programmed by a complex field cooling routine. [41,42,45] More simply, the bias is set by saturating the system with an external field >4 T, which is commonly available with superconducting magnets. As illustrated by states v and vi in Figure 4d, the AFM is inverted in comparison to states iii and iv, leading to an opposite exchange bias shift.…”

Section: Resultsmentioning

confidence: 99%

Tailoring Exchange‐Dominated Synthetic Layered Antiferromagnets: From Collective Magnetic Reversal to Exchange Bias

Bøhm

Hellwig

2022

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Section: Resultsmentioning

confidence: 99%

Tailoring Exchange‐Dominated Synthetic Layered Antiferromagnets: From Collective Magnetic Reversal to Exchange Bias

Bøhm

Hellwig

2022

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“…Nature gives a series of properties for magnetic iron oxides, such as low cost, easy preparation, better biocompatibility, simple modification which renders them better heterostructure materials substrate. [ 20,21 ] Magnetic nanoparticles (MNPs) are always regarded as hard templates to construct the simple, facile nanomaterials with straightforward way. The hard template method for the MNP preparation could control the size and uniformity of the nano‐structure.…”

Section: Introductionmentioning

confidence: 99%

Virus‐Like Magnetic Heterostructure: an Outstanding Metal‐Complex Active Platform Enables High‐Efficiency Separation and Catalysis

Guo¹,

Zhang²,

He³

et al. 2023

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Assembled heterostructure systems, as emerging functional materials, have broad applications ranging from enzyme and drug payload to catalysis and purification. However, these require trial‐ and ‐error design process and complex experimental environment to generate heterostructure materials. Here, this study describes an easy‐to‐execute strategy to fabricate magnetic heterostructure as multifunctional delivery system. We utilize first‐row transition metal copper and nitroso/amino ligand as modules to assemble around Fe3O4 magnetic nanoparticles by excessed mild stimuli and fabricate the magnetic heterostructure materials (Fe3O4@ TACN NPs (tetraamminecopper (II) nitrate)). Notably, the Fe3O4@ TACN NPs present with cat's‐whisker structure containing ligand and metal center. The nitroso‐group ligands exhibit strong binding affinity to heme‐structure enzyme, ensuring effective capture and isolate of cytochrome C (Cyt‐c), resulting in their excellent isolation property. The copper complex‐powered magnetic heterostructure materials can effectively isolation Cyt‐c from complex biological sample (pork heart). Importantly, the Fe3O4@ TACN NPs coordinated with heme‐structure, induced methionine 80 (Met80) disassociates from heme prosthetic group, and contributed to peroxidase‐like (POD‐like) activities increasing. These results exhibit that copper complex‐powered magnetic heterostructure materials can not only satisfy the Cyt‐c isolation and immobilization in an alkaline medium, but also be of the potential for improving the immobilization enzyme reactor performance.

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“…Modifications of functional material properties at the nanoscale can form the basis for achieving materials with tunable response to external stimuli that are beyond the scope of natural homogeneous materials. − For instance, local magnetic property modulations can open pathways for the manipulation of spin waves, , skyrmions, , and bit-patterning for information storage and in producing nanoscale magnetic sensing devices . The most powerful form of modification is to vary locally the intrinsic magnetic properties such as the saturation magnetization ( M s ) and Gilbert damping (α) since these influence the crucial application-relevant properties such as magnetic reversal fields, microwave absorption line widths, and magneto-resistive effects.…”

Section: Introductionmentioning

confidence: 99%

Depth-Adjustable Magnetostructural Phase Transition in Fe₆₀V₄₀ Thin Films

Anwar

Cansever

Boehm

et al. 2022

ACS Appl. Electron. Mater.

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Phase transitions occurring within spatially confined regions can be useful for generating nanoscale material property modulations. Here we describe a magneto-structural phase transition in a binary alloy, where a structural transition from short-range order (SRO) to body centered cubic (bcc) results in the formation of depth-adjustable ferromagnetic layers, which reveal application-relevant magnetic properties of high saturation magnetization (M s) and low Gilbert damping (α). Here we use Fe60V40 binary alloy films which transform from initially M s = 17 kA/m (SRO structure) to 747 kA/m (bcc structure) driven by atomic displacements caused by penetrating ions. Simulations show that an estimated ∼1 displacement per atom triggers a structural transition, forming homogeneous ferromagnetic layers. The thickness of a ferromagnetic layer increases as a step-like function of the ion fluence. Microwave excitations of the ferromagnetic/non-ferromagnetic layered system reveals an α = 0.0027 ± 0.0001. The combination of nanoscale spatial confinement, low α, and high M s provides a pathway for the rapid patterning of magnetic and microwave device elements.

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Highly Tunable Magnetic and Magnetotransport Properties of Exchange Coupled Ferromagnet/Antiferromagnet-Based Heterostructures

Cited by 3 publications

References 71 publications

Tailoring Exchange‐Dominated Synthetic Layered Antiferromagnets: From Collective Magnetic Reversal to Exchange Bias

Tailoring Exchange‐Dominated Synthetic Layered Antiferromagnets: From Collective Magnetic Reversal to Exchange Bias

Virus‐Like Magnetic Heterostructure: an Outstanding Metal‐Complex Active Platform Enables High‐Efficiency Separation and Catalysis

Depth-Adjustable Magnetostructural Phase Transition in Fe₆₀V₄₀ Thin Films

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Highly Tunable Magnetic and Magnetotransport Properties of Exchange Coupled Ferromagnet/Antiferromagnet-Based Heterostructures

Cited by 3 publications

References 71 publications

Tailoring Exchange‐Dominated Synthetic Layered Antiferromagnets: From Collective Magnetic Reversal to Exchange Bias

Tailoring Exchange‐Dominated Synthetic Layered Antiferromagnets: From Collective Magnetic Reversal to Exchange Bias

Virus‐Like Magnetic Heterostructure: an Outstanding Metal‐Complex Active Platform Enables High‐Efficiency Separation and Catalysis

Depth-Adjustable Magnetostructural Phase Transition in Fe60V40 Thin Films

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Depth-Adjustable Magnetostructural Phase Transition in Fe₆₀V₄₀ Thin Films