Intrinsically High Magnetic Performance in Core–Shell Structural (Sm,Y)Fe<sub>12</sub>‐Based Permanent Magnets

Zhao, Lizhong; Su, Rui; Lin, Wen; Li, Wei; Liu, Xiaolian; Zhang, Zhenhua; Zhao, Rongzhi; Han, Yuyan; Zhang, Xue Feng

doi:10.1002/adma.202203503

Cited by 11 publications

(7 citation statements)

References 45 publications

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“…[16] The core-shell nanostructure is another example of nanoscale ordering to enhance the exchange coupling between magnetic functional components. [46,47] As shown in Figure 4d, a coreshell ordered nanostructure with Nd 2 Fe 14 B cores and a-Fe shells were fabricated by self-assembly in alloy melt. [47] In such ordered structure, sufficient exchange coupling between the hardmagnetic Nd 2 Fe 14 B phase and the soft-magnetic a-Fe phase enables a good combination of high remanent magnetization (B r ) and high H c , see Figure 4d.…”

Section: Ordered Permanent-magnet Materialsmentioning

confidence: 99%

Perspective and Prospects for Ordered Functional Materials

Zhang

2023

Advanced Science

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Many functional materials are approaching their performance limits due to inherent trade‐offs between essential physical properties. Such trade‐offs can be overcome by engineering a material that has an ordered arrangement of structural units, including constituent components/phases, grains, and domains. By rationally manipulating the ordering with abundant structural units at multiple length scales, the structural ordering opens up unprecedented opportunities to create transformative functional materials, as amplified properties or disruptive functionalities can be realized. In this perspective article, a brief overview of recent advances in the emerging ordered functional materials across catalytic, thermoelectric, and magnetic materials regarding the fabrication, structure, and property is presented. Then the possibility of applying this structural ordering strategy to highly efficient neuromorphic computing devices and durable battery materials is discussed. Finally, remaining scientific challenges are highlighted, and the prospects for ordered functional materials are made. This perspective aims to draw the attention of the scientific community to the emerging ordered functional materials and trigger intense studies on this topic.

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Section: Ordered Permanent-magnet Materialsmentioning

confidence: 99%

Perspective and Prospects for Ordered Functional Materials

Zhang

2023

Advanced Science

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“…To demonstrate the versatility and the rapid assembly process, Nd-Fe-B permanent magnets were chosen due to their susceptibility of harsh conditions and poor corrosion resistance. [53][54][55] After immersion, the Nd-Fe-B surface exhibited hierarchical scale roughness (Figure 5a) and the surface was rendered superhydrophobic with water contact angle of 169.5°, compared with 86.7° on bare Nd-Fe-B surface (Figure 5d). EDS mapping in Figure S14 (Supporting Information) presents that Nd-Fe-B surface was fully covered with FAS-SiO 2 @PDA coatings and a minor amount of Fe was detected from the underlying Nd-Fe-B.…”

Section: Corrosion Protection For Nd-fe-b Permanent Magnetsmentioning

confidence: 99%

Constructing Superhydrophobicity by Self‐Assembly of SiO₂@Polydopamine Core‐Shell Nanospheres with Robust Oil‐Water Separation Efficiency and Anti‐Corrosion Performance

Shi

Zeng

Yuan

et al. 2023

Adv Funct Materials

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Vulnerable robustness of superhydrophobic materials have mightily hindered their practical applications. Herein, a controllable and effective strategy is demonstrated for constructing robust superhydrophobicity with aqueous hydrophobic interaction driving self-assembly (HIDS), using polydopamine (PDA) as the binder and SiO 2 particles as the nano-sized structures to enable low-adhesive property. The proposed strategy realizes the rapid interfacial assembly of PDA by manipulating the wetting properties of SiO 2 @PDA coreshell particles with hydrophobic modifier. The polyurethane (PU) sponges are facilely rendered superhydrophobic with remarkable robustness, stemming from the excellent adherence of HIDS enhanced covalent interaction between PDA and PU. Coated sponge possesses ultralong-term stability during the oil-water separation, the separation efficiency can be maintained at 98.8% even after 1000 cycle separations and strikingly, superhydrophobicity is still retained after 100 cycle abrasion with ultrahigh loading pressure of 49 kPa. Versatilely, the coatings can be assembled on various substrates through scalable dip coating for attaining superhydrophobicity, regardless of size, roughness, chemistry, and rigidity. The complete water-repellent coatings on permanent magnet of Nd-Fe-B hold excellent anti-corrosion properties without deteriorating the magnetic properties, exhibiting a low corrosion current density of 2.03 × 10 −8 A cm −2 , which is three orders of magnitude lower than that of 1.30 × 10 −5 A cm −2 for bare Nd-Fe-B magnet.

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“…Addressing these challenges requires a multidisciplinary approach, integrating insights from materials science, mechanical engineering, and device physics to develop robust solutions that can withstand the rigors of daily use without compromising the inherent benefits of OLED technology [11,12] . By optimizing material properties and device architectures, researchers aim to significantly improve the durability of flexible OLED displays, ensuring they meet the evolving demands of consumers and the electronics market [13,14] .…”

Section: Introductionmentioning

confidence: 99%

18‐3: Research on Improving the Back Impact resistance of Flexible OLED Modules

Feng,

Zhang,

Pan

et al. 2024

Symp Digest of Tech Papers

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This study focuses on the enhancement of back‐impact resistance in flexible OLED modules, a critical aspect for the durability of modern slim‐profile electronic devices. Under rear compressive forces, flexible OLED modules are prone to bending towards the glass cover, placing the outermost touch layer under significant tensile strain. The brittle nature of the inorganic film within the touch layer, coupled with its low fracture elongation, predisposes it to crack initiation under stress. This mechanical vulnerability can lead to catastrophic failure of the OLED functionality due to moisture and oxygen infiltration, manifesting as black spots on the display. Addressing this, we propose a dual‐faceted approach: optimizing stress distribution by the module design and enhancing the tensile strength of the touch layer's inorganic film, achieving a sixfold increase in the module's resistance to back compression. This paper outlines the experimental setup, finite element method (FEM) simulations, and the resultant implications for flexible OLED module design and durability.

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Intrinsically High Magnetic Performance in Core–Shell Structural (Sm,Y)Fe₁₂‐Based Permanent Magnets

Cited by 11 publications

References 45 publications

Perspective and Prospects for Ordered Functional Materials

Perspective and Prospects for Ordered Functional Materials

Constructing Superhydrophobicity by Self‐Assembly of SiO₂@Polydopamine Core‐Shell Nanospheres with Robust Oil‐Water Separation Efficiency and Anti‐Corrosion Performance

18‐3: Research on Improving the Back Impact resistance of Flexible OLED Modules

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Intrinsically High Magnetic Performance in Core–Shell Structural (Sm,Y)Fe12‐Based Permanent Magnets

Cited by 11 publications

References 45 publications

Perspective and Prospects for Ordered Functional Materials

Perspective and Prospects for Ordered Functional Materials

Constructing Superhydrophobicity by Self‐Assembly of SiO2@Polydopamine Core‐Shell Nanospheres with Robust Oil‐Water Separation Efficiency and Anti‐Corrosion Performance

18‐3: Research on Improving the Back Impact resistance of Flexible OLED Modules

Contact Info

Product

Resources

About

Intrinsically High Magnetic Performance in Core–Shell Structural (Sm,Y)Fe₁₂‐Based Permanent Magnets

Constructing Superhydrophobicity by Self‐Assembly of SiO₂@Polydopamine Core‐Shell Nanospheres with Robust Oil‐Water Separation Efficiency and Anti‐Corrosion Performance