Chapter 6. Design of Metal-free Nanocatalysts

Nanoparticle Design and Characterization for Catalytic Applications in Sustainable Chemistry Pub Date : 2019-05-10 DOI:10.1039/9781788016292-00163

Anaclet Nsabimana, Guobao Xu

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Abstract

Nanomaterials exhibit unique properties that are different from their bulk counterparts as decreasing the size of a particle leads to a larger portion of the atoms being located on the surface, resulting in the increased influence of surface effects on the properties of a material. Owing to these properties, nanocatalysts are considered to be a bridge between homogeneous and heterogeneous catalysis. Metal nanocatalysts, especially platinum catalysts, are important in electrochemical and organic transformation reactions. Unfortunately, their scarcity, low stability, risk to the environment and high cost limit their use. To overcome these challenges, significant work has been performed to synthesize metal-free nanocatalysts such as fullerene, graphitic carbon nitride, porous carbons, graphene, carbon fibres, carbon nanotubes, pure and doped carbons with non-metallic elements (B, N, H, O, P, S…), and so forth, as an alternative to metal-based catalysts. This chapter describes the progress in this field, with a focus on catalyst characterization and their performance, both in electrocatalysis and in organic transformations.

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第六章。无金属纳米催化剂的设计

纳米材料表现出不同于其块状材料的独特特性，因为减小粒子的尺寸会导致大部分原子位于表面，从而增加表面效应对材料特性的影响。由于这些性质，纳米催化剂被认为是均相催化和非均相催化之间的桥梁。金属纳米催化剂，尤其是铂催化剂，在电化学和有机转化反应中具有重要作用。不幸的是，它们的稀缺性、低稳定性、环境风险和高成本限制了它们的使用。为了克服这些挑战，人们已经进行了大量的工作来合成无金属纳米催化剂，如富勒烯、石墨氮化碳、多孔碳、石墨烯、碳纤维、碳纳米管、含非金属元素(B、N、H、O、P、S…)的纯碳和掺杂碳，等等，作为金属基催化剂的替代品。本章描述了这一领域的进展，重点介绍了催化剂的表征及其在电催化和有机转化中的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nanoparticle Design and Characterization for Catalytic Applications in Sustainable Chemistry

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