Novel synthesis of olefin-linked covalent organic frameworks via aldol condensation

doi:10.16085/j.issn.1000-6613.2021-0025

Abstract

Abstract:

Three new olefin-linked covalent organic frameworks were successfully constructed via Aldol condensation by using 2,4,6-trimethyl-1,3,5-triazine (TMT) with C₃-symmetry and aromatic aldehydes as building units. Under hydrothermal conditions, TMT-TFPT-COF [with 2,4,6-tris(4-formylphenyl)-1,3,5-triazine (TFPT)] and TMT-TFB-COF [with benzene-1,3,5-tricarboxaldehyde (TFB)] were successfully synthesized using NaOH as catalyst, while TMT-TFBA-COF [with 2,3,5,6-tetrafluorobenzene-1,4-dicarbaldehyde (TFBA)] was constructed via trifluoroacetic acid (TFA) catalyst. The COFs structures and olefin-linkages were illustrated by theoretical modeling, FTIR and other characterization methods. The results indicated that all these COFs were constructed via two-dimensional eclipsed structure, and the fluorescent COFs (TMT-TFPT-COF and TMT-TFB-COF) would show great potential applications in the photocatalysis and chemical sensors.

Key words: covalent organic frameworks (COFs), porous organic materials, olefin linkage, Aldol condensation

摘要：

具有C₃对称性的三甲基三嗪（TMT）分别与2,4,6-三(4-醛基苯基)-1,3,5-三嗪（TFPT）、均三苯甲醛（TFB）和四氟对苯二甲醛（TFBA）在酸或者碱催化条件下发生Aldol缩合反应，成功构建出3种新型的碳碳双键桥联的共价有机框架材料（TMT-TFPT-COF、TMT-TFB-COF、TMT-TFBA-COF）。本研究通过Material Studio、ZEO⁺⁺等软件对材料进行结构的精确解析，并结合粉末X射线衍射（PXRD）、傅里叶红外光谱（FTIR）等表征手段确定了材料的结构、连接方式及其荧光特性。结果表明，这3种较高结晶度的新型共价有机框架材料均为二维层层堆积结构，其中碱催化条件下合成的TMT-TFPT-COF、TMT-TFB-COF材料呈现出良好的荧光性质，此类荧光COFs材料在光催化、化学传感器等方面具有很好的应用潜力。

关键词: 共价有机框架材料, 多孔有机材料, 碳碳双键, Aldol反应

CLC Number:

TB32

CHEN Jiansong, SUN Nannan, GAO Qiang, WEI Wei. Novel synthesis of olefin-linked covalent organic frameworks via aldol condensation[J]. Chemical Industry and Engineering Progress, 2021, 40(12): 6765-6776.

陈建松, 孙楠楠, 高强, 魏伟. 基于Aldol缩合反应的碳碳双键共价有机框架材料的设计合成[J]. 化工进展, 2021, 40(12): 6765-6776.

Figures/Tables 15

References 27

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原子	x/a	y/b	z/c	原子	x/a	y/b	z/c
H1	0.5632	0.1603	1.0	C10	-0.9990	-0.4846	1.0
H2	0.3991	0.2557	1.0	C11	-1.1656	-0.5350	1.0
C3	0.6006	0.3478	1.0	C12	-0.9625	-0.3323	1.0
C4	-0.6468	-0.4016	1.0	C13	-0.8738	-0.3083	1.0
C5	-0.8479	-0.3737	1.0	H14	-0.8285	-0.2386	1.0
N6	-0.7330	-0.4198	1.0	H15	-0.9049	-0.5180	1.0
C7	-1.0260	-0.4209	1.0	H16	-1.0438	-0.5552	1.0
C8	-1.1202	-0.4492	1.0	H17	-0.9813	-0.2821	1.0
C9	-0.9137	-0.4618	1.0	N18	0.6837	0.4159	1.0

原子	x/a	y/b	z/c	原子	x/a	y/b	z/c
H1	0.5632	0.1603	1.0	C10	-0.9990	-0.4846	1.0
H2	0.3991	0.2557	1.0	C11	-1.1656	-0.5350	1.0
C3	0.6006	0.3478	1.0	C12	-0.9625	-0.3323	1.0
C4	-0.6468	-0.4016	1.0	C13	-0.8738	-0.3083	1.0
C5	-0.8479	-0.3737	1.0	H14	-0.8285	-0.2386	1.0
N6	-0.7330	-0.4198	1.0	H15	-0.9049	-0.5180	1.0
C7	-1.0260	-0.4209	1.0	H16	-1.0438	-0.5552	1.0
C8	-1.1202	-0.4492	1.0	H17	-0.9813	-0.2821	1.0
C9	-0.9137	-0.4618	1.0	N18	0.6837	0.4159	1.0

原子	x/a	y/b	原子	x/a	y/b
H1	0.3549	0.3728	C5	0.3811	0.5779
H2	0.6382	0.6273	N6	0.4693	0.7143
C3	0.5634	0.5197	C7	0.6145	0.4228
C4	0.4306	0.4801	C8	0.5263	0.2814

原子	x/a	y/b	原子	x/a	y/b
H1	0.3549	0.3728	C5	0.3811	0.5779
H2	0.6382	0.6273	N6	0.4693	0.7143
C3	0.5634	0.5197	C7	0.6145	0.4228
C4	0.4306	0.4801	C8	0.5263	0.2814

原子	x/a	y/b	z/c	原子	x/a	y/b	z/c
N1	0.6895	0.4054	0.5	C7	0.7368	0.3813	0.5
C2	0.8556	0.4122	0.5	H8	0.8177	0.4809	0.5
C3	0.8058	0.4297	0.5	H9	0.8392	0.3595	0.5
C4	0.9292	0.4589	0.5	F10	0.9444	0.3636	0.5
C5	0.9596	0.5291	0.5	F11	1.0762	0.4393	0.5
C6	1.0291	0.5692	0.5