Enhanced photocatalytic dye degradation and hydrogen production ability of Bi$_{25}$FeO$_{40}$-rGO nanocomposite and mechanism insight

TL;DR

This study compares Bi$_{25}$FeO$_{40}$-rGO and BiFeO$_{3}$-rGO nanocomposites, revealing that the former exhibits enhanced photocatalytic dye degradation and hydrogen production under visible light, with insights into the underlying mechanisms.

Contribution

It introduces a synthesis method for Bi$_{25}$FeO$_{40}$-rGO nanocomposites and demonstrates their superior photocatalytic performance over BiFeO$_{3}$-rGO and commercial catalysts.

Findings

Bi$_{25}$FeO$_{40}$-rGO outperforms BiFeO$_{3}$-rGO in dye degradation

Bi$_{25}$FeO$_{40}$-rGO shows higher hydrogen production efficiency

Both nanocomposites are more effective than pure BiFeO$_{3}$ and Degussa P25 titania

Abstract

A comprehensive comparison between Bi$_{25}$FeO$_{40}$-reduced graphene oxide(rGO) nanocomposite and BiFeO$_{3}$-rGO nanocomposite has been performed to investigate their photocatalytic abilities in degradation of Rhodamine B dye and generation of hydrogen by water-splitting. The hydrothermal technique adapted for synthesis of the nanocomposites provides a versatile temperature-controlled phase selection between perovskite BiFeO$_{3}$ and sillenite Bi$_{25}$FeO$_{40}$. Both perovskite and sillenite structured nanocomposites are stable and exhibit considerably higher photocatalytic ability over pure BiFeO$_{3}$ nanoparticles and commercially available Degussa P25 titania. Notably, Bi$_{25}$FeO$_{40}$- rGO nanocomposite has demonstrated superior photocatalytic ability and stability under visible light irradiation than that of BiFeO$_{3}$-rGO nanocomposite. The possible mechanism behind the superior photocatalytic performance of Bi$_{25}$FeO$_{40}$-rGO nanocomposite has been critically discussed.