Extraordinary Magnetic Hardening in Nanowire Assemblies: the Geometry and Proximity Effects

Mohapatra, Jeotikanta; Xing, Meiying; Elkins, Jacob; Beatty, Julian; Liu, J. Ping

doi:10.1002/adfm.202010157

Cited by 27 publications

(18 citation statements)

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“…A strong dipolar interaction can make it difficult for NPs to rotate their magnetization directions, leading to dipole ferromagnetism with enhanced coercivity, as observed for 15 nm Co NP arrays by Fresnel Lorentz microscopy and electron holography (Figure C,D) . However, when single-domain magnetic nanowires are considered, their coercivity H c can decrease with increased nanowire packing fraction ( p ): in which H c0 is the coercivity of noninteracting nanowires (i.e., for p ≈ 0), where both the magnetocrystalline anisotropy and shape anisotropy prevail, and A is the proximity coefficient. The quantity Ap represents the induced magnetostatic interaction field, and its value is proportional to both the assembly packing fraction and the spontaneous magnetization of neighboring nanowires.…”

Section: Magnetic Properties Of Nanoparticlesmentioning

confidence: 97%

“…As these nanowires have an average diameter of 8 nm and length of 150 nm, their radius is smaller than the coherent radius ( R coh = 3.65 l ex , where l ex is the exchange length), and they exhibit coherent Stoner–Wohlfarth-type magnetization reversal behavior. As a result, a large coercivity of over 12.6 kOe can be obtained from their aligned assembly (Figure B) . The prealigned nanowires were compacted at various pressures to consolidate the assemblies with the packing densities ranging from 5.3 to 7.3 g/cm 3 and energy products as high as 20 MGOe (Figures C,D) .…”

Section: Anisotropic Magnetic Nanoparticle Arrays For Permanent Magnetsmentioning

confidence: 98%

“…(B) Magnetization loop of the aligned Co nanowire assembly (along the parallel direction) at 300 K. (C) SEM image of the compacted and aligned nanowire assembly. (D) Second-quadrant B – H , M – H , and ( BH ) max – H curves of the compacted nanowire assembly at 300 K. Reproduced with permission from ref . Copyright 2021 Wiley-VCH.…”

Section: Anisotropic Magnetic Nanoparticle Arrays For Permanent Magnetsmentioning

confidence: 99%

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Magnetic Nanoparticles: Synthesis, Anisotropy, and Applications

et al. 2021

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Anisotropy is an important and widely present characteristic of materials that provides desired direction-dependent properties. In particular, the introduction of anisotropy into magnetic nanoparticles (MNPs) has become an effective method to obtain new characteristics and functions that are critical for many applications. In this review, we first discuss anisotropy-dependent ferromagnetic properties, ranging from intrinsic magnetocrystalline anisotropy to extrinsic shape and surface anisotropy, and their effects on the magnetic properties. We further summarize the syntheses of monodisperse MNPs with the desired control over the NP dimensions, shapes, compositions, and structures. These controlled syntheses of MNPs allow their magnetism to be finely tuned for many applications. We discuss the potential applications of these MNPs in biomedicine, magnetic recording, magnetotransport, permanent magnets, and catalysis. CONTENTS 4.5.1. Co-Based Rare-Earth Metal Alloy Nanoparticles 3917 4.5.2. Fe-Based Rare-Earth Metal Alloy Nanoparticles 4.6. Rare-Earth-Metal-Free Nanoparticles 4.6.1. MnBi and MnAl Nanoparticles 4.6.2. Metal Carbide Nanoparticles 5. Magnetic Nanoparticles with Enhanced Anisotropy for Biomedical Applications 5.1. Magnetic Nanoparticles for MRI 5.1.1. MRI in General 5.1.2. Magnetic Nanoparticles as MRI Contrast AgentS 5.1.3. Cubic Ferrite Nanoparticles as T 2 -Weighted MRI Contrast Agents 5.1.4. Cubic Ferrite Nanoparticles as T 1 -Weighted MRI Contrast Agents 5.

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Section: Magnetic Properties Of Nanoparticlesmentioning

confidence: 97%

Section: Anisotropic Magnetic Nanoparticle Arrays For Permanent Magnetsmentioning

confidence: 98%

Section: Anisotropic Magnetic Nanoparticle Arrays For Permanent Magnetsmentioning

confidence: 99%

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Magnetic Nanoparticles: Synthesis, Anisotropy, and Applications

et al. 2021

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“…Nanochemistry has recently made some decisive contributions in the field of hard magnetic materials and PMs by controlling the anisotropic growth of single‐domain and single‐crystal magnetic nanorods (NR), which exhibit high coercivity at room temperature. [ 23 ] Single‐domain cobalt NRs, prepared by organometallic chemistry [ 24 ] or polyol process, [ 25,26 ] combine shape and magnetocrystalline anisotropies. Thanks to their small diameter, which favors uniform magnetization reversal, and their very good crystallinity, which limits the nucleation of magnetization reversal on structural defects, [ 27 ] these objects exhibit coercivity close to the theoretical anisotropy field

H_{normala} = \frac{2 K_{1}}{M_{normalS}} + 2 π M_{normalS}

, with K 1 the magnetocrystalline constant of cobalt and M S its saturation magnetization, the 2 πM S term being related to the shape anisotropy.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Ni–Co–Ni Structures Prepared by Magnetophoresis as Efficient Permanent Magnets for Integration into Microelectromechanical Systems

et al. 2022

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The direct integration of performant permanent magnets (PMs) within miniaturized circuits remains both a scientific and a technological challenge. Magnetophoresis‐driven capillary assembly of hard magnetic nanoparticles is a promising approach to fabricate 3D rare‐earth‐free PMs. However, this process implies the use of soft magnetic blocks to generate the magnetic field gradients required to localize the assembly directly onto silicon substrates. The impact of these soft elements onto the overall magnetic properties is evaluated using Co nanorods as hard material and 150 μm–thick Ni blocks. As expected, the presence of Ni softens the overall properties of the hybrid magnet obtained, but PM properties are preserved for reduced Ni volumes. Magnetic induction as high as 19 mT at a distance of 200 μm is generated by the hybrid Ni–Co–Ni structures, allowing for the electromagnetic actuation of a microelectromechanical resonant sensor.

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“…One of the important magnetic properties is coercivity (Hc), which is a measure of the ability of a ferromagnetic material to keep its magnetization (i.e., without being demagnetized) when Nanomaterials 2021, 11, 3034 2 of 18 exposed to an external magnetic field [16]. Ferromagnetic materials with high coercivity are called magnetically hard and are used to make permanent magnets [17]. Materials with low coercivity are known as soft magnetic materials, which are used in many applications such as transformers [18], recording heads [19], microwave devices [20], and magnetic shielding [21].…”

Section: Introductionmentioning

confidence: 99%

Iron-Nickel Alloy with Starfish-like Shape and Its Unique Magnetic Properties: Effect of Reaction Volume and Metal Concentration on the Synthesized Alloy

et al. 2021

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Iron-nickel alloy is an example of bimetallic nanostructures magnetic alloy, which receives intensive and significant attention in recent years due to its desirable superior ferromagnetic and mechanical characteristics. In this work, a unique starfish-like shape of an iron-nickel alloy with unique magnetic properties was presented using a simple, effective, high purity, and low-cost chemical reduction. There is no report on the synthesis of such novel shape without complex precursors and/or surfactants that increase production costs and introduce impurities, so far. The synthesis of five magnetic iron-nickel alloys with varying iron to nickel molar ratios (10–50% Fe) was undertaken by simultaneously reducing Fe(II) and Ni(II) solution using hydrazine hydrate as a reducing agent in strong alkaline media for 15 min at 95–98 °C. The effect of reaction volume and total metal concentration on the properties of the synthesized alloys was studied. Alloy morphology, chemical composition, crystal structure, thermal stability, and magnetic properties of synthesized iron-nickel alloys were characterized by means of SEM, TEM, EDX, XRD, DSC and VSM. ImageJ software was used to calculate the size of the synthesized alloys. A deviation from Vegard’s law was recorded for iron molar ration higher than 30%., in which superstructure phase of FeNi3 was formed and the presence of defects in it, as well as the dimensional effects of nanocrystals. The saturation magnetization (Ms), coercivity (Hc), retentivity (Mr), and squareness are strongly affected by the molar ratio of iron and nickel and reaction volume as well as the total metal concentration.

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Extraordinary Magnetic Hardening in Nanowire Assemblies: the Geometry and Proximity Effects

Cited by 27 publications

References 60 publications

Magnetic Nanoparticles: Synthesis, Anisotropy, and Applications

Magnetic Nanoparticles: Synthesis, Anisotropy, and Applications

Hybrid Ni–Co–Ni Structures Prepared by Magnetophoresis as Efficient Permanent Magnets for Integration into Microelectromechanical Systems

Iron-Nickel Alloy with Starfish-like Shape and Its Unique Magnetic Properties: Effect of Reaction Volume and Metal Concentration on the Synthesized Alloy

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