Pt/C催化乙二醇选择性氧化制乙醇酸

石油炼制与化工 ›› 2026, Vol. 57 ›› Issue (2): 174-181.

Pt/C催化乙二醇选择性氧化制乙醇酸

张天航,岳于杰,刘旭颖,李玉茹,丁朝英,张玉龙,翁育靖

河南理工大学化学化工学院，河南省煤炭绿色转化重点实验室

收稿日期:2025-08-19 修回日期:2025-11-14 出版日期:2026-02-12 发布日期:2026-01-27
通讯作者: 张天航 E-mail:13409231854@163.com
基金资助:
国家自然科学基金;河南理工大学安全学科基金

Pt/C-CATALYZED SELECTIVE OXIDATION OF ETHYLENE GLYCOL TO GLYCOLIC ACID

Received:2025-08-19 Revised:2025-11-14 Online:2026-02-12 Published:2026-01-27
Supported by:
National Natural Science Foundation of China;Henan Polytechnic University

摘要/Abstract

摘要： 常压下乙二醇（EG）选择性氧化制乙醇酸（GA）是构建绿色碳循环与合成高值化学品的关键环节。采用Pt/C催化体系，系统考察了反应温度、氧气分压、反应助剂类型对反应性能的影响。结果表明，高压条件下最优反应温度为60～80 °C，反应活化能为11.27 kJ/mol，GA选择性高达90%，且氧气反应级数仅为0.24，证实了在微正压条件下即可实现高效催化。半连续微正压反应装置实现了70%的GA选择性。助剂筛选试验表明，抗坏血酸的引入显著提升了反应转化率和选择性[转化率达46%，乙醇醛（GD）和GA总选择性为100%]，而醌类助剂虽能增强活性氧的传输，但对转化率的提升作用有限。通过原位红外光谱分析，明确了EG通过GD中间体转化为GA的串联反应路径。

关键词: 乙二醇, 乙醇酸, 乙醇醛, Pt/C催化剂, 选择性氧化, 自由基调控

Abstract: The selective oxidation of ethylene glycol (EG) to glycolic acid (GA) under ambient pressure constitutes a crucial process for building a green carbon cycle and synthesizing value-added chemicals. This study employed a Pt/C catalytic system to systematically investigate the effects of reaction temperature, oxygen partial pressure, and types of reaction promoter on the reaction performance. The results indicate that the optimal reaction temperature ranges from 60 to 80 °C, with an apparent activation energy of 11.27 kJ/mol. A high GA selectivity of 90% was achieved, and the reaction order with respect to oxygen was determined to be only 0.24, confirming that highly efficient catalysis can be realized under mild positive oxygen pressure. Furthermore, a semi-continuous mild positive-pressure reaction system achieved a GA selectivity of 70%. Screening of reaction promoters revealed that the introduction of ascorbic acid significantly enhanced both reaction conversion and selectivity [with a conversion rate of 46% and total selectivity for glycolaldehyde (GD) and GA reaching 100%]. In contrast, quinone-based promoters, while facilitating active oxygen transport, showed limited improvement in conversion. In situ infrared spectroscopy analysis elucidated the tandem reaction pathway, wherein EG is converted to GA via a GD intermediate.

Key words: ethylene glycol, glycolic acid, glycolaldehyde, Pt/C catalyst, selective oxidation, radical regulation

张天航岳于杰刘旭颖李玉茹丁朝英张玉龙翁育靖. Pt/C催化乙二醇选择性氧化制乙醇酸[J]. 石油炼制与化工, 2026, 57(2): 174-181.

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