Architectural Design and Microstructural Engineering of Metal–Organic Framework‐Derived Nanomaterials for Electromagnetic Wave Absorption

Xu, Xueqing; Li, Deshun; Li, Li; Yang, Zhiwang; Lei, Ziqiang; Xu, Yuxi

doi:10.1002/sstr.202200219

Cited by 29 publications

(17 citation statements)

References 182 publications

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“…Apart from that, the attenuation constant ( α ) is also a key evaluation indicator of an ideal EMW absorber. α can be used to characterize the intrinsic attenuation capacity of the absorber, which can be can be evaluated using the following eqn (17): 65,66 …”

Section: Resultsmentioning

confidence: 99%

Ultra-broadband microwave absorption of (Mn_0.2Fe_0.2Zn_1.2)_x substituted Co₂Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Liu,

Li,

Yan

et al. 2023

J. Mater. Chem. A

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Section: Resultsmentioning

confidence: 99%

Ultra-broadband microwave absorption of (Mn_0.2Fe_0.2Zn_1.2)_x substituted Co₂Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Liu,

Li,

Yan

et al. 2023

J. Mater. Chem. A

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“…This phenomenon leads to an intensified attenuation of incident EMW via the alternating polarized field causing enhanced polarization loss. [ 44,45 ] According to Figure 4a, the polarization loss of OV 2 C‐2 at 70 °C (“1 state”) is higher than that at 25 °C (“0 state”). The SEM result shows that VO 2 grow on the surface of V 2 C, indicating that the heterointerfaces between V 2 C and VO 2 are the main source of polarization loss.…”

Section: Resultsmentioning

confidence: 99%

Integrated Electromagnetic Device with On‐Off Heterointerface for Intelligent Switching Between Wave‐Absorption and Wave‐Transmission

Pan

Pei

Chen

et al. 2023

Adv Funct Materials

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Intelligent electromagnetic wave absorbers (IEAs) are in high demand due to their dynamic electromagnetic parameters that can adapt to the complex and volatile application environments of the current 5G era. Despite of this, there is currently a lack of research on the convertible electromagnetic wave (EMW) absorption mode (switching between wave‐absorption and wave‐transmission) and their integrated design with external physical stimulations, so that the electromagnetic device will realize intelligent switching in any conditions. In this work, a V2C‐VO2(M) heterostructure that exhibits a reversible metal–insulator transition at the temperature of 62 °C is fabricated via oxidation of MXene. The heterostructures demonstrate near wave‐transmission characteristics at 25 °C while wave‐absorption behavior with wide effective absorption bandwidth (4.04 GHz) at 70 °C. VO2(M) exhibits stronger intrinsic conductivity after phase transition, and the “on‐off” heterostructure between V2C and VO2 lead to poor/strong local conductive network and interfacial polarization in 25/70 °C, thus creating “quantized” dielectric loss. Furthermore, a multilayered electromagnetic functional device is developed to facilitate the absorber's phase transition temperature at a voltage of 17.5 V. This work presents promising opportunities of the V2C‐VO2(M) heterostructure for various applications, including radar stealth, portable stealth suits, signal regulation, and deicing.

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“…[6] Therefore, there is an urgent need to explore a feasible strategy for achieving controlling the EM properties of MAMs, enabling the production of high-performance MAMs with thin thickness, lightweight, wide absorption bandwidth, and strong absorption to navigate complex EM environments and embracing the intelligent era. [7][8][9] The microwave absorption (MA) performance of materials is greatly influenced by their intrinsic EM parameters. The physical and chemical characteristics, such as conductivity, permeability, and dielectric properties, as well as the morphology of materials affect the intrinsic EM parameters of materials, therefore affecting the MA performance.…”

Section: Introductionmentioning

confidence: 99%

Structure–Activity Relationship in Microstructure Design for Electromagnetic Wave Absorption Applications

Tian

et al. 2023

Small Structures

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Microwave absorbing materials (MAMs) are materials that effectively absorb incident electromagnetic (EM) wave energy, reducing reflection and scattering. They play a crucial role in enhancing electronic reliability, healthcare, and defense security. However, traditional MAMs like ferrites, magnetic metals, and polymers possess certain limitations, including low impedance matching, narrow absorption bandwidth, poor chemical stability, and high filling ratio, which hinder their further development. To address the requirements of lightweight, wideband, and high‐efficiency absorption, precise structural design has emerged as a captivating research focus. Additionally, comprehending the structure–property relationships between these unique microstructures and EM response and loss mechanisms still poses significant challenges. Herein, a comprehensive review of MAMs is presented with varied structural designs encompassing various scales, providing a detailed introduction of the relationship between various potential structural designs of MAMs and their corresponding EM characteristics and loss mechanisms. Moreover, EM theoretical calculation models, characterization, and analysis methods are discussed. Finally, the article proposes the challenges and prospects for the development of structural design EM wave absorbers.

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Architectural Design and Microstructural Engineering of Metal–Organic Framework‐Derived Nanomaterials for Electromagnetic Wave Absorption

Cited by 29 publications

References 182 publications

Ultra-broadband microwave absorption of (Mn_0.2Fe_0.2Zn_1.2)_x substituted Co₂Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Ultra-broadband microwave absorption of (Mn_0.2Fe_0.2Zn_1.2)_x substituted Co₂Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Integrated Electromagnetic Device with On‐Off Heterointerface for Intelligent Switching Between Wave‐Absorption and Wave‐Transmission

Structure–Activity Relationship in Microstructure Design for Electromagnetic Wave Absorption Applications

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Architectural Design and Microstructural Engineering of Metal–Organic Framework‐Derived Nanomaterials for Electromagnetic Wave Absorption

Cited by 29 publications

References 182 publications

Ultra-broadband microwave absorption of (Mn0.2Fe0.2Zn1.2)x substituted Co2Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Ultra-broadband microwave absorption of (Mn0.2Fe0.2Zn1.2)x substituted Co2Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Integrated Electromagnetic Device with On‐Off Heterointerface for Intelligent Switching Between Wave‐Absorption and Wave‐Transmission

Structure–Activity Relationship in Microstructure Design for Electromagnetic Wave Absorption Applications

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Product

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Ultra-broadband microwave absorption of (Mn_0.2Fe_0.2Zn_1.2)_x substituted Co₂Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure

Ultra-broadband microwave absorption of (Mn_0.2Fe_0.2Zn_1.2)_x substituted Co₂Y hexaferrites with a self-aligned sheet stacked, highly c-axis oriented and multi-domain structure