Abstract

An interlayer structure hybrid wrinkled silica titania (WST) loaded on graphitic carbon nitride (g-C3N4) was successfully constructed using facile microwave-assisted solid-state technique. The as-prepared materials were characterized using N2 adsorption-desorption, XRD, FESEM, UV–Vis DRS, FTIR, and TEM analysis. The photocatalytic degradation of 2-chlorophenol (2-CP) towards visible light illumination (150 mW/cm2) is following the sequence: 10 wt% WST@CN (91%) > 5 wt% WST@CN (65%) > g-C3N4 (63%) > 15 wt% WST@CN (58%) ˃ WST (50%). The supreme photocatalytic performance of 10 wt% WST@CN was owing to the WST morphology that more concealed between stacked layer of g-C3N4, as a consequence of the stronger interaction between “nitrogen pots” of the g-C3N4 and Si/Ti species of the 10 wt% WST, and thus, enhanced the efficiency of charge separation. These criteria provide better charge carrier mobility for enhanced visible light driven photocatalytic performance. The kinetic studies revealed that the photocatalytic degradation of 2-CP using 10 wt% WST@CN obeyed a model of pseudo-first order, with the surface reaction being the rate determining step. Subsequently, the scavenger study confirmed that hydroxyl radicals that absorbed on the catalyst surface play a major role over 10 wt% WST@CN as emerged from the mechanism of Z-scheme. It is notable that the interfacial of WST@CN composite could appear as an excellent catalyst for its useful application for endocrine disruptive wastewater treatment.

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