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Interfacial and Defective Construction from Diverse Cu<sub><i>x</i></sub>S<sub><i>y</i></sub> Quantum Dots toward Broadband Carbon-Based Microwave Absorber

Zhihao Sun, Zihao Guo, Shaoyao Tian, Jingyu Bi, Guangshen Li, Ying Sha, Jianshu Wang, Lanling Zhao, Lei Qian

2024ACS Nano15 citationsDOI

Abstract

In this study, highly monodisperse copper sulfide (Cu x S y ) quantum dots (QDs) have been successfully obtained using a ligand-chemistry strategy, and then a variety of S-deficient Cu x S y /nitrogen-doped carbon (NC) heterointerfaces are constructed by compositional fine-tuning (Cu 9 S 5 → Cu 1.96 S → Cu). First-principles calculations show that the S-deficient domains of Cu x S y QDs and N-doped domains of carbon synergistically enhance the electron transfer from Cu x S y to NC. In addition, the finite element simulations demonstrate that the diverse Cu x S y QDs exhibit their intrinsic size and dielectric confinement effects to precisely manipulate the electric field distortion and improve the relaxation polarization. Consequently, Cu x S y @NC achieves excellent impedance matching and a strong loss mode dominated by dielectric polarization. Among them, Cu x S y @NC-650 has a maximum effective absorption bandwidth of 7.7 GHz at 2.5 mm, while Cu x S y @NC-700 features a minimum reflection loss of −66.7 dB at 13.7 GHz, respectively. Furthermore, the simulations of radar cross-sections have confirmed that the Cu x S y @NC series is promising in the field of radar stealth.

Topics & Concepts

Quantum dotMicrowaveMaterials scienceCarbon fibersBroadbandOptoelectronicsCarbon quantum dotsNanotechnologyPhysicsOpticsQuantum mechanicsComposite numberComposite materialElectromagnetic wave absorption materialsAdvanced Antenna and Metasurface TechnologiesCarbon and Quantum Dots Applications