Controlling N speciation in solution synthesis of N-doped carbon materials†

RSC Applied Interfaces Pub Date : 2025-06-11 DOI:10.1039/D5LF00064E

Mi Yeon Byun, Lili Liu, Daniel Mejía-Rodríguez, Eric D. Walter, Zihua Zhu, Niri Govind, Tom Autrey and Maria L. Sushko

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Abstract

Carbon-based materials, such as graphite and its functionalized/doped derivatives, are promising lightweight layered materials for hydrogen activation and storage. Their propensity to control the thermodynamics of hydrogen binding and the kinetics of hydrogen mobility strongly depends on the speciation and the arrangement of dopants. In this study, we demonstrate precise control over dopant speciation and clustering in nitrogen-containing layered carbon materials during hydrothermal synthesis. Through extensive spectroscopic characterization and first principles simulations, we demonstrate that the formation of N-motifs can be controlled by the choice of precursor and synthesis temperature. The distinct three-dimensional architecture and porosity in graphene oxide and carbon nitride-derived materials furnish a synthetic pathway for precise control over the local and global structure of nitrogen-doped carbon materials and their activity toward the activation of molecular hydrogen.

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氮掺杂碳材料溶液合成中氮形态的控制

碳基材料，如石墨及其功能化/掺杂衍生物，是很有前途的用于氢活化和储存的轻质层状材料。它们控制氢结合热力学和氢迁移动力学的倾向很大程度上取决于掺杂剂的形态和排列。在这项研究中，我们证明了水热合成过程中对含氮层状碳材料中掺杂物形态和聚类的精确控制。通过广泛的光谱表征和第一性原理模拟，我们证明了n -基序的形成可以通过前驱体和合成温度的选择来控制。氧化石墨烯和氮化碳衍生材料中独特的三维结构和孔隙度为精确控制氮掺杂碳材料的局部和全局结构及其对氢分子活化的活性提供了一条合成途径。

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RSC Applied Interfaces

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