Zhe Su, Shan Yi, Wanyu Zhang, Xiaxi Xu, Yayun Zhang, Shenghu Zhou, Bo Niu, Donghui Long
{"title":"限制在碳纳米片中的超细富空Nb2O5半导体增强了高衰减微波吸收的介电极化","authors":"Zhe Su, Shan Yi, Wanyu Zhang, Xiaxi Xu, Yayun Zhang, Shenghu Zhou, Bo Niu, Donghui Long","doi":"10.1007/s40820-023-01151-0","DOIUrl":null,"url":null,"abstract":"<div><p>The integration of nano-semiconductors into electromagnetic wave absorption materials is a highly desirable strategy for intensifying dielectric polarization loss; achieving high-attenuation microwave absorption and realizing in-depth comprehension of dielectric loss mechanisms remain challenges. Herein, ultrafine oxygen vacancy-rich Nb<sub>2</sub>O<sub>5</sub> semiconductors are confined in carbon nanosheets (ov-Nb<sub>2</sub>O<sub>5</sub>/CNS) to boost dielectric polarization and achieve high attenuation. The polarization relaxation, electromagnetic response, and impedance matching of the ov-Nb<sub>2</sub>O<sub>5</sub>/CNS are significantly facilitated by the Nb<sub>2</sub>O<sub>5</sub> semiconductors with rich oxygen vacancies, which consequently realizes an extremely high attenuation performance of − 80.8 dB (> 99.999999% wave absorption) at 2.76 mm. As a dielectric polarization center, abundant Nb<sub>2</sub>O<sub>5</sub>–carbon heterointerfaces can intensify interfacial polarization loss to strengthen dielectric polarization, and the presence of oxygen vacancies endows Nb<sub>2</sub>O<sub>5</sub> semiconductors with abundant charge separation sites to reinforce electric dipole polarization. Moreover, the three-dimensional reconstruction of the absorber using microcomputer tomography technology provides insight into the intensification of the unique lamellar morphology regarding multiple reflection and scattering dissipation characteristics. Additionally, ov-Nb<sub>2</sub>O<sub>5</sub>/CNS demonstrates excellent application potential by curing into a microwave-absorbing, machinable, and heat-dissipating plate. 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引用次数: 2
摘要
将纳米半导体集成到电磁波吸收材料中是提高介质极化损耗的理想策略;实现高衰减微波吸收和深入理解介质损耗机理仍然是挑战。本文将富氧空位的超细Nb2O5半导体封装在碳纳米片(ov-Nb2O5/CNS)中,以增强介质极化并实现高衰减。具有丰富氧空位的Nb2O5半导体显著促进了ov-Nb2O5/CNS的极化弛缓、电磁响应和阻抗匹配,从而在2.76 mm处实现了−80.8 dB (> 99.999999%波吸收)的极高衰减性能。丰富的Nb2O5 -碳异质界面作为介电极化中心,可使界面极化损失加剧,从而增强介电极化,而氧空位的存在使Nb2O5半导体具有丰富的电荷分离位点,从而增强电偶极子极化。此外,利用微型计算机断层扫描技术对吸收器进行三维重建,可以深入了解独特的片层形态在多重反射和散射耗散特性方面的增强。此外,ov-Nb2O5/CNS通过固化成吸波、可加工和散热的板材,显示出良好的应用潜力。这项工作为纳米半导体/碳复合材料的介电极化损耗机制提供了新的思路,并为高性能微波吸收材料的设计提供了灵感。
Ultrafine Vacancy-Rich Nb2O5 Semiconductors Confined in Carbon Nanosheets Boost Dielectric Polarization for High-Attenuation Microwave Absorption
The integration of nano-semiconductors into electromagnetic wave absorption materials is a highly desirable strategy for intensifying dielectric polarization loss; achieving high-attenuation microwave absorption and realizing in-depth comprehension of dielectric loss mechanisms remain challenges. Herein, ultrafine oxygen vacancy-rich Nb2O5 semiconductors are confined in carbon nanosheets (ov-Nb2O5/CNS) to boost dielectric polarization and achieve high attenuation. The polarization relaxation, electromagnetic response, and impedance matching of the ov-Nb2O5/CNS are significantly facilitated by the Nb2O5 semiconductors with rich oxygen vacancies, which consequently realizes an extremely high attenuation performance of − 80.8 dB (> 99.999999% wave absorption) at 2.76 mm. As a dielectric polarization center, abundant Nb2O5–carbon heterointerfaces can intensify interfacial polarization loss to strengthen dielectric polarization, and the presence of oxygen vacancies endows Nb2O5 semiconductors with abundant charge separation sites to reinforce electric dipole polarization. Moreover, the three-dimensional reconstruction of the absorber using microcomputer tomography technology provides insight into the intensification of the unique lamellar morphology regarding multiple reflection and scattering dissipation characteristics. Additionally, ov-Nb2O5/CNS demonstrates excellent application potential by curing into a microwave-absorbing, machinable, and heat-dissipating plate. This work provides insight into the dielectric polarization loss mechanisms of nano-semiconductor/carbon composites and inspires the design of high-performance microwave absorption materials.
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.