Exploring n‐π* Electronic Transitions in Graphitic Carbon Nitride: Fundamentals, Strategies, and Photocatalytic Advances
Bangwang Li, Tong Tian, Youbin Zheng, Daochuan Jiang, Gengsheng Xu, Yingqiang Sun, Zhongjun Li, Yupeng Yuan
Abstract
Abstract Photocatalysis utilizes solar energy to drive redox reactions, offering a promising solution to global energy and environmental challenges. Up to now, graphitic carbon nitride (g‐C 3 N 4 ) has been widely studied due to its unique organic structural framework and favourable electronic properties. However, its photocatalytic efficiency is often constrained by a limited light absorption range (up to ~460 nm) and modest charge‐carrier mobility. Recent findings suggest that n‐π* electronic transitions can extend the absorption edge of g‐C 3 N 4 to approximately 600 nm, enhancing the activity. Herein, we first outline the fundamental structural and electronic features of g‐C 3 N 4 , highlighting the role of both n‐π* electronic transitions. We then provide a comprehensive overview of various strategies for activating n‐π* transitions, emphasizing the necessity of distorting the planar and symmetric tri‐s‐triazine units to enable this transition. The subsequent sections demonstrate how modulating n‐π* transitions can broaden the light absorption spectrum and facilitate more efficient charge separation, thereby enhancing photocatalytic processes. Finally, we propose potential future directions for exploiting n‐π* transitions to further advance g‐C 3 N 4 ‐based photocatalysts. This review aims to fill a gap in the literature by providing a focused summary of n‐π* transitions in g‐C 3 N 4 and their significance for sustainable energy and environmental applications.