Realizing radio-frequency epsilon-near-zero response via embedding cobalt nanoparticles into polyimide

IF 6.5 2区 材料科学 Q1 MATERIALS SCIENCE, COMPOSITES
Jinjiu Qi , Yuan Yuan , Qifa He , Pengtao Yang , Hua-Xin Peng , Runhua Fan
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Abstract

Epsilon-near-zero (ENZ) materials have drawn considerable attention due to their enticing properties, such as large wavelength, quasi-static and tunneling. Most research on ENZ behaviors is conducted in the visible, microwave, and infrared bands, but there is seldom research in radio frequency (MHz ∼ GHz). In this work, polyimide (PI) embedded cobalt nanoparticles (NPs) were fabricated to realize ENZ behavior in MHz-bands. The percolation networks were constructed and the dielectric resonance frequency was observed for PI-35 wt% Co composite at 580 MHz. As Co content increased, the ENZ response was obtained due to dielectric resonance and plasma oscillation. Also, conduction mechanism of PI/Co composites undergo a change from hopping state to metal-like state. The reactance value changed from negative to positive with increasing frequency, corresponding to the transition of permittivity from positive to negative value.

Abstract Image

通过将钴纳米粒子嵌入聚酰亚胺实现射频ε近零响应
ε-近零(ENZ)材料因其诱人的特性而备受关注,如大波长、准静态和隧道效应。有关 ENZ 行为的研究大多在可见光、微波和红外波段进行,但很少有射频(MHz ∼ GHz)方面的研究。在这项研究中,我们制作了嵌入钴纳米粒子(NPs)的聚酰亚胺(PI),以实现 MHz 波段的 ENZ 行为。构建了渗滤网络,并观察到 PI-35 wt% Co 复合材料的介电共振频率为 580 MHz。随着 Co 含量的增加,介电共振和等离子振荡产生了 ENZ 响应。此外,PI/Co 复合材料的传导机制也从跳跃状态转变为类金属状态。随着频率的增加,电抗值从负值变为正值,这与介电常数从正值变为负值是相对应的。
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来源期刊
Composites Communications
Composites Communications Materials Science-Ceramics and Composites
CiteScore
12.10
自引率
10.00%
发文量
340
审稿时长
36 days
期刊介绍: Composites Communications (Compos. Commun.) is a peer-reviewed journal publishing short communications and letters on the latest advances in composites science and technology. With a rapid review and publication process, its goal is to disseminate new knowledge promptly within the composites community. The journal welcomes manuscripts presenting creative concepts and new findings in design, state-of-the-art approaches in processing, synthesis, characterization, and mechanics modeling. In addition to traditional fiber-/particulate-reinforced engineering composites, it encourages submissions on composites with exceptional physical, mechanical, and fracture properties, as well as those with unique functions and significant application potential. This includes biomimetic and bio-inspired composites for biomedical applications, functional nano-composites for thermal management and energy applications, and composites designed for extreme service environments.
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