Boosting Interfacial Polarization Through Heterointerface Engineering in MXene/Graphene Intercalated-Based Microspheres for Electromagnetic Wave Absorption

IF 31.6 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nano-Micro Letters Pub Date : 2023-06-07 DOI:10.1007/s40820-023-01123-4

Ge Wang, Changfeng Li, Diana Estevez, Peng Xu, Mengyue Peng, Huijie Wei, Faxiang Qin

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引用次数: 4

Abstract

Multi-layer 2D material assemblies provide a great number of interfaces beneficial for electromagnetic wave absorption. However, avoiding agglomeration and achieving layer-by-layer ordered intercalation remain challenging. Here, 3D reduced graphene oxide (rGO)/MXene/TiO₂/Fe₂C lightweight porous microspheres with periodical intercalated structures and pronounced interfacial effects were constructed by spray-freeze-drying and microwave irradiation based on the Maxwell–Wagner effect. Such approach reinforced interfacial effects via defects introduction, porous skeleton, multi-layer assembly and multi-component system, leading to synergistic loss mechanisms. The abundant 2D/2D/0D/0D intercalated heterojunctions in the microspheres provide a high density of polarization charges while generating abundant polarization sites, resulting in boosted interfacial polarization, which is verified by CST Microwave Studio simulations. By precisely tuning the 2D nanosheets intercalation in the heterostructures, both the polarization loss and impedance matching improve significantly. At a low filler loading of 5 wt%, the polarization loss rate exceeds 70%, and a minimum reflection loss (RL_min) of −67.4 dB can be achieved. Moreover, radar cross-section simulations further confirm the attenuation ability of the optimized porous microspheres. These results not only provide novel insights into understanding and enhancing interfacial effects, but also constitute an attractive platform for implementing heterointerface engineering based on customized 2D hierarchical architectures.

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利用异质界面工程增强MXene/石墨烯插层微球电磁波吸收的界面极化

多层二维材料组合提供了大量有利于电磁波吸收的界面。然而，避免团聚和实现逐层有序嵌入仍然是一个挑战。利用麦克斯韦-瓦格纳效应，采用喷雾冷冻干燥和微波辐照法制备了具有周期性插层结构和明显界面效应的3D还原氧化石墨烯/MXene/TiO2/Fe2C轻量多孔微球。该方法通过引入缺陷、多孔骨架、多层组装和多组分体系增强界面效应，导致协同损失机制。微球中丰富的2D/2D/0D/0D插层异质结提供了高密度的极化电荷，同时产生了丰富的极化位点，从而增强了界面极化，CST Microwave Studio模拟验证了这一点。通过对二维纳米片在异质结构中的嵌入进行精确调整，极化损耗和阻抗匹配都得到了显著改善。当填充量为5 wt%时，极化损耗率超过70%，最小反射损耗(RLmin)为- 67.4 dB。此外，雷达截面模拟进一步证实了优化后多孔微球的衰减能力。这些结果不仅为理解和增强界面效应提供了新的见解，而且为实现基于定制二维层次结构的异质界面工程提供了一个有吸引力的平台。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nano-Micro Letters NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

42.40

自引率

4.90%

发文量

715

审稿时长

13 weeks

期刊介绍： Nano-Micro Letters is a peer-reviewed, international, interdisciplinary and open-access journal that focus on science, experiments, engineering, technologies and applications of nano- or microscale structure and system in physics, chemistry, biology, material science, pharmacy and their expanding interfaces with at least one dimension ranging from a few sub-nanometers to a few hundreds of micrometers. Especially, emphasize the bottom-up approach in the length scale from nano to micro since the key for nanotechnology to reach industrial applications is to assemble, to modify, and to control nanostructure in micro scale. The aim is to provide a publishing platform crossing the boundaries, from nano to micro, and from science to technologies.