Ni/Zn/Al类水滑石非贵金属催化剂的制备及其在醇胺法合成N-取代吲哚类化合物中的应用

doi:10.6023/A24030077

摘要/Abstract

N-取代吲哚是一类重要的杂环化合物, 在医药、功能化材料、有机液体储氢等领域有着广泛应用. 本工作采用共沉淀法合成了一系列类水滑石催化剂, 首次实现了非贵金属催化乙二醇和N-取代苯胺为原料一步合成N-取代吲哚的方法. 研究了通过改变元素组成对催化活性的影响, 得到催化剂Ni_1.5Zn_1.5Al₁的活性最高, 其中Ni元素为主要活性组分起催化作用, Zn元素可协同Ni元素促进反应发生. 通过X射线衍射(XRD)、热重分析(TGA)、电感耦合等离子发射光谱(ICP-OES)和N₂物理吸附分析(BET)对Ni/Zn/Al系列催化剂进行了结构与组成的分析. 所提供的合成方案能够有效地应用于不同类型N-取代吲哚的合成. 与现有方法相比, 摆脱了贵金属的限制, 且催化剂在经历5次循环后仍能保持良好的催化活性, 具有原料价格低、生产成本低、操作工艺简单、环境友好、原子利用率高等优点.

关键词: 水滑石, 非贵金属, N-取代吲哚衍生物, 醇胺法

Indole derivatives are an extremely important class of heterocyclic compounds with extensive applications in fields such as medicine and biology. In recent years, with the development of organic liquid hydrogen storage technology, its application scope has been continuously expanding. There have been many reports on the synthesis of indole, among which the synthesis of monosubstituted indole mainly involves direct halogenation of indole and direct cyclization of aromatic amines and alcohols. The former requires a large amount of halogenated reagents and excessive inorganic salts, resulting in poor environmental compatibility. The latter is a very ideal synthesis method with advantages such as high atomic efficiency and environmental friendliness, but currently all reported cases require the participation of precious metals. Therefore, the development of inexpensive non precious metal catalysts based on biomass ethylene glycol as raw material for the synthesis of N-substituted indole compounds has important scientific research significance and application value in large-scale production and application in the fields of medicine and hydrogen energy. In the current study, a series of hydrotalcite like catalysts using the coprecipitation method were prepared and applied in the one-step synthesis of N-substituted indoles using ethylene glycol and N-substituted anilines. By changing the elemental composition of hydrotalcite like catalysts, the optimal elemental composition was selected as Ni_1.5Zn_1.5Al₁, with Ni as the main active component playing a catalytic role, Zn element can synergistically promote the reaction with Ni element, while aluminum element is a structural maintenance component without catalytic activity. The structure and composition of Ni/Zn/Al hydrotalcite catalysts were analyzed by X-ray diffraction (XRD), thermogravimetric analysis (TGA), inductively coupled plasma-optical emission spectrometer (ICP-OES), and N₂ physical adsorption analysis (BET), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). This strategy can be effectively applied to N-alkyl and aryl indole derivatives. Compared with reported methods, it overcomes the limitations of precious metals, and the catalyst can maintain good catalytic activity after five cycles. It has the advantages of low raw material price, low production cost, simple operation process, friendly environment and high atomic utilization rate.

Key words: hydrotalcite, non-noble metal, N-substituted indole derivatives, alcoholamine method

引用此文

李雷, 唐鋆磊, 王丽涛, 李江涛, 全洪林, 林冰, 王宏, 李佳奇, 周太刚. Ni/Zn/Al类水滑石非贵金属催化剂的制备及其在醇胺法合成N-取代吲哚类化合物中的应用[J]. 化学学报, 2024, 82(7): 748-754.

Lei Li, Junlei Tang, Litao Wang, Jiangtao Li, Honglin Quan, Bing Lin, Hong Wang, Jia-Qi Li, Taigang Zhou. Preparation of Ni/Zn/Al Type Hydrotalcite Non-Noble Metal Catalysts and Application in the Synthesis of N-Substituted Indole Derivatives Via Alcoholamine Method[J]. Acta Chimica Sinica, 2024, 82(7): 748-754.

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图/表 7

图1. 醇胺法合成N-甲基吲哚

Figure 1. Synthesis of N-methylindole by alcoholamine method

图2. (a)水滑石制备示意图; (b)三种NiZnAl水滑石的XRD图; (c)三种水滑石的TGA图; (d)三种水滑石的DTG图; (e) TEM扫描mapping区域图; (f)~(h) Ni、Zn、Al三种元素在水滑石中的分布图

Figure 2. (a) Preparation diagram of hydrotalcite; (b) XRD patterns of three NiZnAl hydrotalcites; (c) TGA diagrams of three types of hydrotalcites; (d) DTG diagrams of three types of hydrotalcites; (e) TEM scanning mapping area map; (f)~(h) distribution diagram of Ni, Zn and Al elements in hydrotalcite

Samples	ICP-OES Molar ratio	Surface area/ (m²•g⁻¹)	BET
Samples	ICP-OES Molar ratio	Surface area/ (m²•g⁻¹)	Pore volume/ (cm³•g⁻¹)	Pore width/ nm
Ni₁Zn₂Al₁	1.03∶2.05∶1	76.75	0.32	14.16
Ni_1.5Zn_1.5Al₁	1.51∶1.53∶1	90.29	0.22	6.93
Ni₂Zn₁Al₁	2.00∶1.03∶1	69.61	0.11	4.32

表1. 三种水滑石的ICP-OES和BET结果

Table 1. ICP-OES and BET results of three types of hydrotalcites

Entry	Catalyst	Additive	2a yield^b/%
1	5% Pd/C	ZnO	1
2	5% Pd/Al₂O₃	ZnO	3
3	5% Pd/Mg₃Al₁	ZnO	16
4	5%Pd/Fe₁Mg₂Al₁	ZnO	17
5	5%Pd/Co₁Mg₂Al₁	ZnO	19
6	5%Pd/Ni₁Mg₂Al₁	ZnO	47
7	0.5%Pd/Ni₁Mg₂Al₁	ZnO	65
8	Ni₁Mg₂Al₁	ZnO	43
9	Ni₁Mg₂Al₁	—	16
10	Zn₁Mg₂Al₁	—	0
11	Ni_0.5Zn_0.5Mg₂Al₁	—	23
12	Ni₁Zn₂Al₁	—	53
13	Ni₁Zn₂Fe₁	—	51
14	Ni₁Zn₂Cr₁	—	30
15	Ni₁Zn₂	—	42
16	Ni_1.5Zn_1.5Al₁	—	55
17	Ni₂Zn₁Al₁	—	17
18^c	Ni_1.5Zn_1.5Al₁	—	16
19^d	Ni_1.5Zn_1.5Al₁	—	66
20^e	Ni_1.5Zn_1.5Al₁	—	42
21^f	Ni_1.5Zn_1.5Al₁	—	52

表2. 反应条件的优化a

Table 2. Optimization of reaction conditionsa

Entry	Substrate	Product	Yield^b/%

表3. 底物拓展结果a

Table 3. Substrate expansion resultsa

图3. 催化剂循环使用性能

Figure 3. Catalyst recycling performance

图4. 机理实验及推测: (A)控制实验; (B)机理推测

Figure 4. Mechanistic study: (A) Control experiment; (B) mechanism proposal

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