Low-frequency plasmonic state and negative permittivity in copper/titanium dioxide percolating composites

The titanium dioxide-based varistor is generally equivalent to a combination of resistor and capacitor, whereas, for the titanium dioxide-based composite with negative permittivity, it can be composed of a resistor, capacitor, and inductor. In this work, ac conductivity, real permittivity, and reactance of copper/titanium dioxide (Cu/TiO2) percolating composites are investigated in detail in the frequency of 10 kHz 1 MHz. As Cu content increases, percolation occurs in composites, accompanied by the transformation of electron transport mechanism from localization to delocalization. Furthermore, the regulation of permittivity by compositions and microstructures is specifically analyzed. It suggests that the enhanced permittivity before percolation ascribes to the enhancement of interfacial polarization, when reaching the excessively percolating state, plasma-like negative permittivity is achieved, consequently, revealing the low-frequency plasmonic state. Moreover, reactance analyses indicate the negative permittivity is ascribed to the inductive characteristics, and the stronger the inductance, the greater the contribution to the negative permittivity.

Automated summary

This study investigates the ac conductivity, real permittivity, and reactance of copper/titanium dioxide percolating composites, revealing that the enhancement of interfacial polarization contributes to the enhanced permittivity before percolation, while plasma-like negative permittivity is achieved in excessively percolating state. Reactance analyses indicate that the negative permittivity is attributed to inductive characteristics, with greater inductance contributing more to the negative permittivity.