▎ 摘　　要

Herein, nonprecious bifunctional composite materials made of vanadium dioxide (VO2) anchored on two-dimensional reduced graphene oxide (2D-rGO) nanosheets (VO2/2D-rGO) via a one-step in situ hydrothermal method were developed. In particular, different polymorphs of VO2 microstructures, that is, VO2(A), VO2(B), VO2(M), and so on, obtained by the influence of beta-MnO2 have been paid much attention because of their wide range of potential applications, especially, in electrochemical water splitting. Accordingly, the electrochemical activity of the VO2/2D-rGO composite for the oxygen evolution reaction and hydrogen evolution reaction (OER and HER) was dramatically amended by tuning the electronic structure of VO2(A) using a cationic additive such as beta-MnO2. Moreover, the obtained VO2(A)/2D-rGO (MVAG) composite was used as a precursor for attaining different polymorph-based composite materials by altering the additive KMnO4. The crystallographic phase transition of the VO2(x) microstructure was systematically studied and confirmed by powder X-ray diffractometer patterns. By varying the additive concentration, three different composite materials were prepared: beta-MnO2-VO2(M)/2D-rGO (MVMG), beta-MnO2-VO2(B)/2D-rGO (MVBG), and beta-MnO2-V2O5/2D-rGO (MVOG). Benefiting from the prismatic type of the VO2(B) microstructure, the MVBG composite material shows enhanced OER (273 mV) and HER (178 mV) activities to achieve a current density of 10 mA cm(-2). Remarkably, the two-electrode system has been constructed using one of the polymorphs such as MVBG parallel to MVBG to study the cell voltage of 1.62 V to reach a current density of 10 mA cm(-2) and displayed a Tafel slope of 108 mV dec(-1). In addition, the MVBG parallel to MVBG system showed outstanding long-term stability for 35 h. This work offers simple and convenient protocols for achieving cost-effective bifunctional composite materials for overall water splitting.