Ji Pengfei, Feng Xuanyu, Oliveres Pau, Li Zhe, Murakami Akiko, Wang Cheng, Lin Wenbin
Department of Chemistry , The University of Chicago , 929 East 57th Street , Chicago , Illinois 60637 , United States.
College of Chemistry and Chemical Engineering, iCHEM, State Key Laboratory of Physical Chemistry of Solid Surface , Xiamen University , Xiamen 361005 , China.
J Am Chem Soc. 2019 Sep 18;141(37):14878-14888. doi: 10.1021/jacs.9b07891. Epub 2019 Sep 4.
The synthesis of highly acidic metal-organic frameworks (MOFs) has attracted significant research interest in recent years. We report here the design of a strongly Lewis acidic MOF, ZrOTf-BTC, through two-step transformation of MOF-808 (Zr-BTC) secondary building units (SBUs). Zr-BTC was first treated with 1 M hydrochloric acid solution to afford ZrOH-BTC by replacing each bridging formate group with a pair of hydroxide and water groups. The resultant ZrOH-BTC was further treated with trimethylsilyl triflate (MeSiOTf) to afford ZrOTf-BTC by taking advantage of the oxophilicity of the MeSi group. Electron paramagnetic resonance spectra of Zr-bound superoxide and fluorescence spectra of Zr-bound -methylacridone provided a quantitative measurement of Lewis acidity of ZrOTf-BTC with an energy splitting (Δ) of 0.99 eV between the π* and π* orbitals, which is competitive to the homogeneous benchmark Sc(OTf). ZrOTf-BTC was shown to be a highly active solid Lewis acid catalyst for a broad range of important organic transformations under mild conditions, including Diels-Alder reaction, epoxide ring-opening reaction, Friedel-Crafts acylation, and alkene hydroalkoxylation reaction. The MOF catalyst outperformed Sc(OTf) in terms of both catalytic activity and catalyst lifetime. Moreover, we developed a ZrOTf-BTC@SiO composite as an efficient solid Lewis acid catalyst for continuous flow catalysis. The Zr centers in ZrOTf-BTC@SiO feature identical coordination environment to ZrOTf-BTC based on spectroscopic evidence. ZrOTf-BTC@SiO displayed exceptionally high turnover numbers (TONs) of 1700 for Diels-Alder reaction, 2700 for epoxide ring-opening reaction, and 326 for Friedel-Crafts acylation under flow conditions. We have thus created strongly Lewis acidic sites in MOFs via triflation and constructed the MOF@SiO composite for continuous flow catalysis of important organic transformations.
近年来,高酸性金属有机框架材料(MOFs)的合成引起了广泛的研究兴趣。在此,我们报告通过对MOF-808(Zr-BTC)二级构筑单元(SBUs)进行两步转化设计出一种强路易斯酸性MOF,即ZrOTf-BTC。首先用1 M盐酸溶液处理Zr-BTC,通过用一对氢氧根和水基团取代每个桥连甲酸根基团得到ZrOH-BTC。利用MeSi基团的亲氧性,将所得的ZrOH-BTC进一步用三氟甲磺酸三甲基硅酯(MeSiOTf)处理得到ZrOTf-BTC。Zr结合超氧化物的电子顺磁共振光谱和Zr结合的α-甲基吖啶的荧光光谱对ZrOTf-BTC的路易斯酸性进行了定量测量,其π和π轨道之间的能量分裂(Δ)为0.99 eV,与均相基准Sc(OTf)相当。结果表明,ZrOTf-BTC是一种在温和条件下对多种重要有机转化反应具有高活性的固体路易斯酸催化剂,包括狄尔斯-阿尔德反应、环氧开环反应、傅克酰基化反应和烯烃氢烷氧基化反应。该MOF催化剂在催化活性和催化剂寿命方面均优于Sc(OTf)。此外,我们开发了一种ZrOTf-BTC@SiO复合材料作为用于连续流动催化的高效固体路易斯酸催化剂。基于光谱证据,ZrOTf-BTC@SiO中的Zr中心具有与ZrOTf-BTC相同的配位环境。在流动条件下,ZrOTf-BTC@SiO对狄尔斯-阿尔德反应的周转数(TONs)高达1700,对环氧开环反应为2700,对傅克酰基化反应为326。因此,我们通过三氟甲磺酰化在MOFs中创建了强路易斯酸性位点,并构建了用于重要有机转化反应连续流动催化的MOF@SiO复合材料。
