Electrospinning Synthesis of NaBiTiO Nanofibers for Dielectric Capacitors in Energy Storage Application

Overview

Journal Nanomaterials (Basel)

Date 2022 Mar 26

PMID 35335719

Authors

Yuan Liu

Hang Luo

Zhe Gao

Haoran Xie

Ru Guo

Fan Wang

Xuefan Zhou

Jun Cao

Dou Zhang

Affiliations

Soon will be listed here.

Abstract

Dielectric composites based on ferroelectric ceramics nanofibers are attracting increasing attention in capacitor application. In this work, the sol-gel method and electrospinning technology are utilized to prepare one-dimensional NaBiTiO (NBT) nanofibers, and the influence of electrospinning process parameters such as spinning voltage, liquid supply rate, and collector speed on the morphology and structure of nanofibers are systematically explored. The final optimized parameters include the applied voltage of 20 kV, the solution flow rate of 1 mL/h, and the collector's rotation speed of 1500 rpm. The optimized NBT nanofibers are introduced into the PVDF polymer matrix for energy storage application. Owing to the enhanced interfacial polarization between PVDF matrix and NBT nanofibers with a high aspect ratio, the NBT-PVDF nanocomposites achieve a high discharge energy density of 14.59 J cm and an energy efficiency of 53.69% at 490 kV mm, which are higher than those of pure PVDF, i.e., 10.26 J cm and 48.17% at 420 kV mm, respectively. The results demonstrate that the strategy of synthesizing NBT nanofibers using the electrospinning method is of great potential for high-performance dielectric capacitor application.

Citing Articles

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