Effect of direct-current biasing on the adjustable radio-frequency negative permittivity characteristics of Bi2SiO5/multiwall carbon nanotube metacomposites

Multiwall carbon nanotube (MWCNT) based metacomposites with negative permittivity have received significant interest over the past decade due to their unique electromagnetic properties. Here, markedly percolating Bi2SiO5 (BSO)/MWCNT metacomposites with adjustable negative permittivity were prepared by the facile hydrothermal method. Three-dimensional conductive networks formed by interconnected MWCNT are present in BSO/MWCNT metacomposites with 10 and 20 wt% of MWCNT. The detailed microstructure and resistivity studies of the metacomposites led to realize that the adjustable negative permittivity of the BSO/MWCNT metacomposites attributes to the low-frequency plasmon resonance of free Drude carriers. In this work, the effect of the direct current biasing voltage in the radio frequency region is investigated on the negative permittivity characteristics. For below percolation threshold (f(c)) metacomposites, the Maxwell-Wagner polarization effects increase in low frequency region immediately after dc bias is applied. In case of above percolation threshold (f(c)) meta composites, the Drude free carrier concentration increases due to the formation of conductive network among MWCNT led to the rise of negative permittivity values in the low frequency region. This work provides a novel strategy for the adjustment of the negative permittivity value, which can expand the potential application in the field of sensors based on the changes in permittivity properties.

Automated summary

Metacomposites of Bi2SiO5 (BSO) and multiwall carbon nanotubes (MWCNT) with adjustable negative permittivity were prepared using a hydrothermal method. The interconnected MWCNT formed a three-dimensional conductive network in the metacomposites, leading to the tunable negative permittivity attributed to the low-frequency plasmon resonance of free Drude carriers. The study also investigated the impact of direct current biasing voltage on the negative permittivity characteristics in the radio frequency region, providing a novel strategy for adjusting the negative permittivity value for potential applications in sensors.