Tailoring Highly N‐Doped Carbon Materials from Hexamine‐Based MOFs: Superior Performance and New Insight into the Roles of N Configurations in Na‐Ion Storage

To prepare highly N‐doped carbon materials (HNCs) as well as to determine the influence of N dopants on Na‐ion storage performance, hexamine‐based metal–organic frameworks are employed as new and efficient precursors in the preparation of HNCs. The HNCs possess reversible capacities as high as 160 and 142 mA h g^?1 at 2 A g^?1 (≈8 C) and 5 A g^?1 (≈20 C), respectively, and maintain values of 145 and 123 mA h g^?1 after 500 cycles, thus exhibiting excellent rate and long‐term cyclic performance. Based on systematic analysis, a new insight into the roles of the different N configurations in Na‐ion storage is proposed. The adsorption of Na ions on pyridinic‐N (N‐6) and pyrrolic‐N (N‐5) is fully irreversible, whereas the adsorption on graphitic‐N (N‐Q) is partially reversible and the adsorption on N‐oxide (N‐O) is fully reversible. More importantly, the N‐6/N‐Q ratio is an intrinsic parameter that reflects the relationship between the N configurations and carbon textures for N‐doped carbons prepared from in situ pyrolysis of organic precursors. The cyclic stability and rate‐performance improve with decreasing N‐6/N‐Q ratio. Therefore, this work is of great significance for the design of N‐doped carbon electrodes with high performance for sodium ion batteries.