硝基苯选择性加氢制对氨基苯酚的研究进展

摘要/Abstract

摘要： 针对硝基苯（NB）催化加氢制备对氨基苯酚（PAP）工艺存在收率和选择性不高、设备腐蚀和环境污染较重，技术优化方向不清晰等问题，系统综述了其反应催化机理、催化剂活性调控原理、催化剂性能优化策略、Bamberger重排机理、介质环境对反应过程的影响机制。分析发现：Pt基催化剂对NB加氢反应具有优异的催化活性，但产物PAP选择性取决于中间体苯基羟胺（PHA）的吸附强度和反应介质环境；催化剂改性的本质在于调控金属中心的电子结构，削弱其对PHA的吸附作用，抑制其过度加氢副反应；通过掺入杂原子、构建核壳结构、形成双金属合金等催化剂改性方法，可实现PAP的高选择性；载体特性对催化剂性能影响很大，溶剂种类和体系酸度对加氢及重排反应有重要影响；利用环境友好介质（CO₂/H₂O体系和固体酸）替代硫酸溶液，可从源头避免副产物硫酸盐的生成，具有显著的绿色化优势。未来，研究应致力于介质-催化剂系统的整体优化，深化对反应-传递耦合机制的理解，推动绿色工艺走向实际应用。

关键词: 对氨基苯酚, 加氢催化剂, 选择性, Bamberger重排, 酸性介质

Abstract: Aiming at the issues in the catalytic hydrogenation of nitrobenzene (NB) to produce p-aminophenol (PAP), such as low yield and selectivity, severe equipment corrosion, environmental pollution, and unclear technological optimization directions, this work systematically reviews the catalytic reaction mechanism, principles of regulating catalyst activity, strategies for optimizing catalyst performance, the mechanism of Bamberger rearrangement, and the influence of the medium environment on the reaction process. Analysis reveals that Pt-based catalysts exhibit excellent catalytic activity for NB hydrogenation, but the selectivity for the product PAP depends on the adsorption strength of the intermediate phenylhydroxylamine (PHA) and the reaction medium environment. The essence of catalyst modification lies in regulating the electronic structure of the metal centers to weaken their adsorption of PHA and suppress the over-hydrogenation side reaction. High selectivity for PAP can be achieved through catalyst modification methods such as doping heteroatoms, constructing core-shell structures, and forming bimetallic alloys. The properties of the support significantly affect catalyst performance, while the type of solvent and system acidity have important impacts on both hydrogenation and rearrangement reactions. Replacing sulfuric acid solutions with environmentally friendly media (CO₂/H₂O systems and solid acids) can prevent the generation of sulfate byproducts at the source, offering significant green advantages. Future research should focus on the holistic optimization of the medium-catalyst system, deepen the understanding of the reaction-transport coupling mechanism, and promote the practical application of green processes.

Key words: p-aminophenol, hydrogenation catalyst, selectivity, Bamberger rearrangement, acidic medium

沈佳蓓陈雷云许立信万超. 硝基苯选择性加氢制对氨基苯酚的研究进展[J]. 石油炼制与化工, 2026, 57(2): 36-44.

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