sp <sup>2</sup> /sp <sup>3</sup> –Hybridized nitrogen–mediated electrochemical CO <sub>2</sub> capture and utilization
Zhenfang Zhang, Yitong Li, Yiwen Zhong, Peng Li, Lingfeng Zhu, Zhi Zheng, Baohua Jia, Matthew David, Yang Fu, Hai Yu, Tianyi Ma
Abstract
Electrochemical carbon dioxide (CO 2 ) capture and utilization, powered by renewable energy, are essential to achieving net-zero emissions and CO 2 valorization. While remarkable progress has been made in catalysts, solution design, and system engineering, recent breakthroughs reveal that nitrogen-containing molecules—specifically sp 2 -hybridized structures (e.g., pyridine) and sp 3 -hybridized moieties (e.g., ethanolamine) —hold untapped potential to revolutionize both CO 2 capture and conversion. These structures have been demonstrated as the Holy Grail in facilitating CO 2 activation, stabilizing key intermediates, and streamlining reaction pathways—capabilities rarely achievable with conventional strategies. However, limited mechanistic understanding of their physicochemical properties and interactions with CO 2 hampers broader application. This review highlights recent advances in leveraging sp 2 /sp 3 -hybridized nitrogen structures, unpacks their molecular roles in electrochemical CO 2 management, and offers a unifying framework for their dual-functionality across capture and conversion. By illuminating these nitrogen-based motifs, we uncover practical design principles and open avenues for integrating expanded N-containing compounds into energy technologies—paving the way for next-generation carbon management strategies.