Succulent-Inspired Implicit Structural Change for Smart “ON/OFF” Switchable and Flexible EMI Shielding Coating

Li, Chenxi; Li, Donglei; Zhang, Mingting; You, Bo; Wu, Zonglin; Tao, Yulin; Sun, Yaojie; Wu, Limin; Mo, Xiaoliang

doi:10.1021/acsami.3c18296

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.3c18296

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Succulent-Inspired Implicit Structural Change for Smart “ON/OFF” Switchable and Flexible EMI Shielding Coating

Chenxi Li,

Donglei Li,

Mingting Zhang

et al.

Abstract: Modern miniaturized intelligent electronics call for smart switchable and flexible electromagnetic interference (EMI) shielding material for highly precise applications. However, most switchable EMI shielding materials are based on an explicit structural change. Herein, we report a succulent-inspired smart switchable MXene (WR-MXene) coating film realized by inner implicit structural change, which benefits from the insertion of our reversible large-cavity yolk−shell biomicrospheres. The novel switchable yolk−s… Show more

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Cited by 2 publications

References 56 publications

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Electrochemically‐Switched Microwave Response of MXene in Organic Electrolyte

Fei,

Li,

et al. 2024

Advanced Materials

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The increasingly complex electromagnetic (EM) environment necessitates advanced electrically controllable electromagnetic interference (EMI) shielding materials that can adapt to varying EM conditions. This study develops a flexible electrochemically tunable EMI shielding device based on ultrathin Ti3C2Tx MXene films, exhibiting reversible shielding effectiveness (SE) modulation from 18.9 to 26.2 dB in X band at 0.1 and −1.5 V. Unlike the previously reported mechanism relying on interlayer spacing adjustments, the work leverages transformations of charging state and surface chemistry for tunability during the electrochemical process. The Ti3C2Tx flake size is also evidenced to play a crucial role, with smaller flakes offering higher absorption modulation despite lower SE modulation, enabling the device with high designability. When integrated with Salisbury screen structure, the device achieves adjustable absorption from 93.560% at 0.1 V to 99.996% at −1 V, showing a tunable reflection suppression ratio up to 32 dB with an effective bandwidth of 4.2 GHz. Additionally, incorporating resonant cavity structure enables absorption‐dominated (over 90%) microwave‐responsive switching at 0.1 and −1.5 V. This work highlights significant potential of adaptive EMI shielding materials for applications in smart electronic protection, EM switch, and radar camouflage.

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Electrochemically‐Switched Microwave Response of MXene in Organic Electrolyte

Fei,

Li,

et al. 2024

Advanced Materials

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Super Tough Multifunctional MXene/PAA‐CS Double Network Hydrogels with High Mechanical Sensing Properties and Excellent EMI Shielding Performance

Mei,

Ouyang,

et al. 2024

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Hydrogels present significant potential in flexible materials designed for electromagnetic interference (EMI) shielding, attributed to their soft, stretchable mechanical properties and water‐rich porous structures. Unfortunately, EMI shielding hydrogels commonly suffer from low mechanical properties, deficient fracture energy, and low strength, which limit the serviceability of these materials in complex mechanical environments. In this study, the double network strategy is successfully utilized along with the Hofmeister effect to create MXene/PAA (polyacrylic acid)‐CS (chitosan) hydrogels and further strengthen and toughen the gel with (NH4)2SO4 solution. The gel exhibits enhanced functionalities such as outstanding stretchability, excellent strain sensitivity (11.66), and super fracture energy (≥9 kJ m−2). Notably, it demonstrates outstanding shielding effectiveness of 73.8 dB in the terahertz (THz) range, and the shielding properties can be effectively tuned by varying the MXene content, the (NH4)2SO4 concentration, and the thickness of the hydrogel. Additionally, the gel shows robust and superior shielding effectiveness after repeated stretching and long‐term dehydration. The MXene/PAA‐CS double‐network (DN) hydrogels would be an excellent candidate for EMI shielding materials in advanced flexible electronic equipment and soft robots.

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Succulent-Inspired Implicit Structural Change for Smart “ON/OFF” Switchable and Flexible EMI Shielding Coating

Cited by 2 publications

References 56 publications

Electrochemically‐Switched Microwave Response of MXene in Organic Electrolyte

Electrochemically‐Switched Microwave Response of MXene in Organic Electrolyte

Super Tough Multifunctional MXene/PAA‐CS Double Network Hydrogels with High Mechanical Sensing Properties and Excellent EMI Shielding Performance

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