多孔层柱磷酸锆在Prins缩合反应中的应用

制备了一系列不同离子交换的多孔氧化硅层柱磷酸锆, 利用N₂吸附-脱附、 扫描电子显微镜和吡啶吸附红外光谱等方法对材料的结构和酸性进行了表征, 并应用于β-蒎烯与多聚甲醛的Prins缩合反应合成诺卜醇. 结果发现, 层柱磷酸锆对此反应具有优异的催化性能, 锌离子的引入可进一步提高诺卜醇的选择性, 从而得到更高的诺卜醇产率, 于80℃反应4 h后β-蒎烯的转化率为91%, 诺卜醇产率达到83%. 酸性表征结果表明, 诺卜醇产率与催化剂表面Lewis酸(L酸)性位的数目以及L酸位/B酸位的比值密切相关. 该催化剂还具有较好的重复利用性能, 反应5次后产率仅下降12%. 催化剂的失活可能是由于酸性位被积碳覆盖所致.     

淀粉模板法制备复合金属氧化物及其催化α-蒎烯氧化性能的研究

以淀粉为生物模板,LDHs晶核溶液为前驱体,通过共沉淀法、陈化及煅烧过程,制备了一系列复合金属氧化物多孔材料.采用X射线衍射(XRD)、扫描电子显微镜(SEM)、X射线能谱(EDX)、N2吸附-脱附(BET)和X射线光电子能谱(XPS)等手段对样品进行形貌、结构与化学组成的表征,并比较它们H2O2-α-蒎烯催化氧化性能.结果表明,淀粉以"嵌入"式发挥模板作用制备出具有独特形貌、孔径分布在约2~5 nm的介孔及大孔尺寸的多金属复合氧化物多孔材料,其比表面积达760.90 m2/g,具有良好的结晶度;其中Mg Zn Al Fe四元复合氧化物催化性能最佳,在α-蒎烯/H2O2摩尔比为1∶1.2、催化剂用量为10.0 mg、溶剂(V(DMF)∶V(水)=4∶1)2 m L、20℃下反应4 h时,α-蒎烯转化率可达53.8%,产物2,3-环氧蒎烷、马鞭草烯醇、马鞭草烯酮的选择性分别为48.9%、2 9.9%、21.3%.     

从《世阿弥传书》到《匠明》:能乐观演空间尺度体系的传承与演变

利用酰胺化反应在2,2,6,6-四甲基哌啶-1-氧自由基(TEMPO)分子的4位引入乙酰氨基和异烟酰氨基分别获得Acet-TEMPO和isoNTA-TEMPO分子.将Acet-TEMPO、 isoNTA-TEMPO和TEMPO分别与MIL-101(Fe)组成共催化体系,以苯甲醇选择性氧化为苯甲醛做模型反应,研究上述3种催化体系的催化性能.催化结果表明3种催化体系的催化活性顺序为:MIL-101(Fe)/isoNTA-TEMPO MIL-101(Fe)/Acet-TEMPOMIL-101(Fe)/TEMPO.通过对比实验和吸附实验表明isoNTA-TEMPO的吡啶官能团与MIL-101(Fe)的Fe簇配位作用是提高体系催化性能的关键因素.MIL-101(Fe)/isoNTA-TEMPO催化体系对各种芳香醇均表现出较好的催化性能,且催化剂能循环回收利用.     

氢化诺卜醇及其烷基醚的合成与表征

由β-蒎烯与多聚甲醛反应制得诺卜醇,然后用Ni(R)催化氢化制得氢化诺卜醇(ROH),再将氢化诺卜醇与亚硫酰氯反应制得氢化诺卜基氯(RCl),由RCl分别与6种醇钠反应合成了6种氢化诺卜基烷基醚,各产物的得率均在92%以上,GC纯度95%以上。各产物都用IR,1H NMR,13C NMR与MS进行了结构表征。     

双功能金属有机骨架材料的制备及催化烯烃环氧化性能

采用转动水热晶化的合成方式, 以ZnO为锌源制备了锌钴金属有机骨架(ZnCo-MOF)双功能催化剂材料; 利用X射线衍射(XRD), 傅里叶变换红外光谱(FTIR), 扫描电子显微镜(SEM)和X射线光电子能谱(XPS)等手段表征了催化剂的形貌、 结构和组成. 该催化剂材料在微波加热辅助催化α-蒎烯和α-甲基苯乙烯双烯烃的空气环氧化反应中, 在不加任何引发剂或共还原剂条件下, 能够高转化率、 高选择性地得到环氧化物. 使用转动水热晶化法(110 r/min转速)合成的ZnCo-MOF催化剂拥有最佳的催化活性, 在对α-蒎烯和α-甲基苯乙烯进行催化环氧化反应时分别得到86.3%和99.8%(摩尔分数)的转化率, 对应的环氧化物的选择性分别达到93.8%和94.3%.     

功能化金属有机骨架负载铂高效催化硅氢加成反应

采用后修饰法合成MIL-101-791,并通过简单的浸渍法制备了Pt/MIL-101-791催化材料.利用傅里叶红外光谱仪（FT-IR）、氮气吸附脱附（BET）、热重分析（TGA）、X射线衍射仪（XRD）、透射电子显微镜（TEM）和X射线光电子能谱仪（XPS）等对催化材料进行表征.采用硅氢加成反应作为Pt/MIL-101-791催化性能的探针.结果表明：Pt成功的分散在MIL-101-791上,并体现出了高效的催化活性和良好的稳定性,循环使用5次后仍能保持较高的催化活性,转化率能保持在85%以上.通过优化该反应的生产条件,得出最佳催化工艺：3%催化剂用量占总底物用量的0.24%,n（APEG）/n（MD^HM）=1.1/1,催化时间为3 h,催化温度为90℃下,MD^HM的转化率高达94%,生成的产品色泽纯净,且在植物表面具备良好的铺展性能.     

苯部分加氢制环己烯新型Ru-B/MOF催化剂

制备了多种金属-有机骨架(MOF)材料,采用浸渍-化学还原法制备了非晶态Ru-B/MOF催化剂,考察了它们在苯部分加氢反应中的催化性能.催化性能评价结果表明,这些催化剂的初始反应速率(r0)顺序为Ru-B/MIL-53(Al)Ru-B/MIL-53(Al)-NH2Ru-B/UIO-66(Zr)Ru-B/UIO-66(Zr)-NH2Ru-B/MIL-53(Cr)Ru-B/MIL-101(Cr)Ru-B/MIL-100(Fe),环己烯初始选择性(S0)顺序为Ru-B/MIL-53(Al)≈Ru-B/MIL-53(Cr)Ru-B/UIO-66(Zr)-NH2Ru-B/MIL-101(Cr)Ru-B/MIL-53(Al)-NH2Ru-B/UIO-66(Zr)≈Ru-B/MIL-100(Fe).催化性能最好的Ru-B/MIL-53(Al)催化剂上的r0和S0分别为23 mmol·min-1·g-1和72%.采用多种手段,对催化性能差异最为显著的Ru-B/MIL-53(Al)和Ru-B/MIL-100(Fe)催化剂的物理化学性质进行了表征.发现MIL-53(Al)载体能够更好地分散Ru-B纳米粒子,粒子的平均尺寸为3.2 nm,而MIL-100(Fe)载体上Ru-B纳米粒子团聚严重,粒径达46.6 nm.更小的粒径不仅能够提供更多的活性位,而且也有利于环己烯选择性的提高.对Ru-B/MIL-53(Al)催化剂的反应条件进行了优化,在180°C和5 MPa的H2压力下,环己烯得率可达24%,展示了MOF材料用作苯部分加氢催化剂载体的良好前景.     

Pt/MIL-101(Cr)在肉桂醛选择性加氢反应中的催化性能

采用简单易行的浸渍法将Pt纳米粒子负载到MIL-101(Cr)上, 制备了Pt/MIL-101(Cr)催化剂, 并对其在肉桂醛选择性加氢反应的催化性能进行了研究。XRD、N₂吸附、TEM和催化性能的研究结果表明, Pt的负载量对负载于MIL-101(Cr)上Pt纳米粒子的尺寸及所制备催化剂对肉桂醇的选择性有很大影响。低Pt负载量(1.0wt%)的Pt/MIL-101(Cr)较其他MOFs和无机材料在肉桂醛选择性加氢反应中表现出了高的催化性能, 在优化的反应条件下肉桂醛转化率和对肉桂醇的选择性可分别达96.5%和86.2%。Pt/MIL-101(Cr)催化剂具有良好的稳定性。Pt/MIL-101(Cr)所表现出的优良的催化性能同MIL-101(Cr)载体的孔道结构及其表面性质密切相关。     

Pt/MIL-101(Cr)在肉桂醛选择性加氢反应中的催化性能

采用简单易行的浸渍法将Pt纳米粒子负载到MIL-101(Cr)上,制备了Pt/MIL-101(Cr)催化剂,并对其在肉桂醛选择性加氢反应的催化性能进行了研究。XRD、N₂吸附、TEM和催化性能的研究结果表明,Pt的负载量对负载于MIL-101(Cr)上Pt纳米粒子的尺寸及所制备催化剂对肉桂醇的选择性有很大影响。低Pt负载量(1.0%)的Pt/MIL-101(Cr)较其他MOFs和无机材料在肉桂醛选择性加氢反应中表现出了高的催化性能,在优化的反应条件下肉桂醛转化率和对肉桂醇的选择性可分别达96.5%和86.2%。Pt/MIL-101(Cr)催化剂具有良好的稳定性。Pt/MIL-101(Cr)所表现出的优良的催化性能同MIL-101(Cr)载体的孔道结构及其表面性质密切相关。     

水相介质中碳酸钾/硫脲联合促进邻位氨基溴转变成α,β-脱氢氨的研究

建立了在水相介质中, 在碳酸钾/硫脲联合促进下, 具有邻位氨基溴的酯和邻位氨基溴的酮在室温下发生溴化氢消除反应, 高收率地制备α,β-脱氢氨(功能化烯胺)的新方法. 共考察了23种不同结构α,β-邻位氨基溴的酯和α,β-邻位氨基溴的酮的反应情况, 证明该方法具有广泛的适应性. 实验发现, 无论底物为α-氨基-β-溴结构还是α-溴-β-氨基结构, 反应过程中都要经过一个氮丙啶过程, 而氮丙啶的开环是区域专一的, 因此产物具有区域专一性(烯键上的氨基均处在羰基的α-位). 所有产物的结构均经过核磁共振波谱及高分辩率质谱确证. 克量级放大实验结果表明, 该方法具有一定的用于工业化生产的可行性.     

Immobilized Pd on a NHC functionalized metal–organic framework MIL-101(Cr): an efficient heterogeneous catalyst in Suzuki−Miyaura coupling reaction in water

A novel Pd−NHC functionalized metal–organic framework (MOF) based on MIL-101(Cr) was synthesized and used as an efficient heterogeneous catalyst in the C-C bond formation reactions. Using this heterogeneous Pd catalyst system, the Suzuki−Miyaura coupling reaction was accomplished well in water, and coupling products were obtained in good to excellent yields in short reaction time. The Pd−NHC−MIL-101(Cr) was characterized using some different techniques, including Fourier transform-infrared, X-ray diffraction, scanning electron microscopy, energy-dispersive X-ray spectroscopy, transmission electron microscopy (TEM), X-ray photoelectron spectroscopy, inductively coupled plasma and elemental analysis. The microscopic techniques showed the discrete octahedron structure of MIL-101(Cr), which is also stable after chemical modification process to prepare the catalyst system. The TEM images of the catalyst showed the existence of palladium nanoparticles immobilized in the structure of the catalyst, while no reducing agent was used. It seems that the NHC groups and imidazolium moieties in the structure of the MOF can reduce Pd (II) to Pd (0) species. This modified MOF substrate can also prevent aggregation of Pd nanoparticles, resulting in high stability of them in organic transformation. The Pd−NHC−MIL-101(Cr) catalyst system could be simply extracted from the reaction mixture, providing an efficient synthetic method for the synthesis of biaryls derivatives using the aforementioned coupling reaction. The Pd−NHC−MIL-101(Cr) catalyst could be recycled in this organic reaction with almost consistent catalytic efficiency.     

A new Brønsted acid MIL-101(Cr) catalyst by tandem post-functionalization; synthesis and its catalytic application

A new heterogeneous Brønsted solid acid catalyst was prepared by tandem post-functionalization of MIL-101(Cr) and utilized for acetic acid esterification and alcoholysis of epoxides under solvent-free conditions. First, MIL-101(Cr) was functionalized with pyrazine to achieve MIL-101(Cr)-Pyz. Afterwards, the nucleophilic reaction of MIL-101(Cr)-Pyz with 1,3-propane sultone and next acidification with diluted sulfuric acid gave MIL-101(Cr)-Pyz-RSO₃H Brønsted solid acid catalyst. Various characterization methods such as Fourier transformation infrared (FT-IR) spectroscopy, X-ray diffraction (XRD), elemental analysis (CHNS), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), energy-dispersiveX-ray(EDX) spectroscopy, thermal analysis (TGA/DTA), acid–base titration, and N₂ adsorption/desorption analysis were employed to fully characterize the prepared catalyst. The catalyst showed high activity compared to unmodified MIL-101(Cr) in both catalytic acetic acid esterification and alcoholysis of epoxides. It can also be readily isolated from the reaction mixture and reused three times without major decrease in its activity.     

PdAg/MIL-101(Fe)催化NaBH4水解制氢

将PdAg纳米颗粒负载到MIL-101(Fe)上作为硼氢化钠水解制氢的催化剂。采用XRD、TEM、HRTEM、XPS、SEM和EDS等方法对催化剂PdAg/MIL-101(Fe)的结构进行了表征。PdAg/MIL-101(Fe)在硼氢化钠水解制氢中表现出较高的催化活性,在温和的条件下水解制氢最大速率为2.60 L·min^–1·g_cat.^–1。详细研究了反应温度、催化剂用量、氢氧化钠和硼氢化钠浓度对该催化反应的影响规律。结果发现,制氢速率很大程度上依赖于反应温度,随着反应温度的升高,制氢速率明显增加,制氢的表观活化能为54.89 kJ·mol^–1。该催化剂重用性能好,5次循环后仍能保持活性。     

Palladium nanoparticles encapsulated in a metal-organic framework as efficient heterogeneous catalysts for direct C2 arylation of indoles

Highly dispersed palladium nanoparticles (Pd NPs) encapsulated in the mesoporous cages of the metal-organic framework (MOF) MIL-101(Cr) have been prepared by using the wetness impregnation method. The Pd NPs were characterized by powder X-ray diffraction (PXRD), N(2) adsorption, transmission electron microscopy, inductively coupled plasma atomic emission spectroscopy (ICP-AES), and X-ray photoelectron spectroscopy (XPS). The particles size ((2.6±0.5) nm) of the obtained Pd NPs was in good agreement with the cage diameters (2.9 and 3.4 nm) of the MOF. The resulting Pd/MIL-101(Cr) catalyst exhibited extremely high catalytic activities in the direct C2 arylation of substituted indoles by using only 0.1 mol% of the Pd catalyst. Moreover, the catalyst is easily recoverable and can be reused several times without leaching into solution and loss of activity. The combination of the highly dispersible Pd NPs within the accessible mesoporous cages and the favorable adsorption of the aryl halides on MIL-101 are suspected to be the main reasons for the observed high activities of the Pd/MIL-101(Cr) catalyst in the direct C2 arylation of indoles.     

短孔道介孔分子筛Zr-Ce-SBA-15固载酸性离子液体催化合成双酚F

通过化学键接的方式,将酸性离子液体(ILs)分别负载于两种不同的硅基载体上,成功制备了SBA-15-ILs(SILs)与Zr-Ce-SBA-15-ILs(ZCSILs)等两种固载化酸性离子液体。 通过傅里叶变换红外光谱仪(FT-IR)、热重分析仪(TG-DTG)、X射线衍射仪(XRD)、N₂吸附-脱附比表面仪(BET)、透射电子显微镜(TEM)、扫描电子显微镜(SEM)与有机元素分析仪(OEA)等对所制备催化剂的物化性能进行了表征,并进一步研究了其在甲醛-苯酚合成二羟基二苯基甲烷(双酚F,BPF)中的催化活性。 结果表明:短孔道的ZCSILs具有较高比表面积、较多的离子液体负载量和相对优异的催化活性。 当m(催化剂)/m(甲醛)=0.36,n(苯酚)/n(甲醛)=30,反应时间90 min、反应温度90 ℃时,BPF收率可达95.6%,对4,4′-BPF的选择性达到44.8%,且所制备的ZCSILs重复使用5次后,依然显示优异的催化活性。     

Copper-doped sulfonic acid-functionalized MIL-101(Cr) metal–organic framework for efficient aerobic oxidation reactions

A series of Cr-based metal–organic framework MIL-101-SO₃H bearing sulfonic acid functional groups were utilized for the immobilization of catalytically active copper species via a post-synthetic metalation method. The novel materials were fully characterized by scanning electron microscopy, X-ray diffraction, energy dispersive X-ray spectroscopy (EDX), X-ray photoelectron spectroscopy (XPS), the Brunauer–Emmett–Teller method, and thermogravimetric analysis. XPS and the EDX element map both suggested that Cu²⁺ is coordinately bonded to the MIL-101-SO₃H, which forms the MIL-101-SO₃@Cu structure. The obtained copper-doped MIL-101-SO₃@Cu-1, MIL-101-SO₃@Cu-2, and MIL-101-SO₃@Cu-3 catalysts were utilized in the selective oxidation of alcohols and epoxidation of olefins using molecular oxygen as an oxidant. Catalytic aerobic oxidation optimization showed that MIL-101-SO₃@Cu-1 is the optimal catalyst and it can be reused ten times without compromising the yield and selectivity.     

金属有机骨架材料MIL-53(Al)负载纳米Pd颗粒：一种CO氧化的活性催化剂

通过等体积浸渍法制备了金属有机骨架材料MIL-53(Al) (MIL：Materials of Institut Lavoisier)负载纳米Pd催化剂. 采用X射线衍射(XRD)、透射电子显微镜(TEM)和X射线光电子能谱(XPS)等手段对催化剂的结构进行了表征. 催化剂在反应前后XRD衍射峰保持不变,说明载体MIL-53(Al)具有良好的稳定性. 采用TEM对催化剂进行表征,结果表明,MIL-53(Al)的多孔晶体结构有助于形成高度分散的纳米Pd颗粒,样品2.7% (w) Pd/MIL-53 中Pd颗粒的平均粒径为2.21 nm. 该催化剂在CO氧化反应中表现出较高的催化活性,115 ℃达到完全转化. 同时催化剂可循环使用,多次反应后催化活性和催化剂结构都保持稳定.     

MIL-100(Fe) Supported Pt−Co Nanoparticles as Active and Selective Heterogeneous Catalysts for Hydrogenation of 1,3-Butadiene

Superior catalytic performance for selective 1,3-butadiene (1,3-BD) hydrogenation can usually be achieved with supported bimetallic catalysts. In this work, Pt−Co nanoparticles and Pt nanoparticles supported on metal–organic framework MIL-100(Fe) catalysts (MIL=Materials of Institut Lavoisier, PtCo/MIL-100(Fe) and Pt/MIL-100(Fe)) were synthesized via a simple impregnation reduction method, and their catalytic performance was investigated for the hydrogenation of 1,3-BD. Pt1Co1/MIL-100(Fe) presented better catalytic performance than Pt/MIL-100(Fe), with significantly enhanced total butene selectivity. Moreover, the secondary hydrogenation of butenes was effectively inhibited after doping with Co. The Pt1Co1/MIL-100(Fe) catalyst displayed good stability in the 1,3-BD hydrogenation reaction. No significant catalyst deactivation was observed during 9 h of hydrogenation, but its catalytic activity gradually reduces for the next 17 h. Carbon deposition on Pt1Co1/MIL-100(Fe) is the reason for its deactivation in 1,3-BD hydrogenation reaction. The spent Pt1Co1/MIL-100(Fe) catalyst could be regenerated at 200 °C, and regenerated catalysts displayed the similar 1,3-BD conversion and butene selectivity with fresh catalysts. Moreover, the rate-determining step of this reaction was hydrogen dissociation. The outstanding activity and total butene selectivity of the Pt1Co1/MIL-100(Fe) catalyst illustrate that Pt−Co bimetallic catalysts are an ideal alternative for replacing mono-noble-metal-based catalysts in selective 1,3-BD hydrogenation reactions.     

Pd/MIL-101的制备及非均相催化吲哚C-H活化

水热合成MIL-101,过量浸渍法吸附Pd(OAc)_2,原位还原Pd~(2+)制得Pd/MIL-101催化剂.采用XRD、XPS、SEM、ICP、HRTEM和N_2吸/脱附实验对其结构进行表征,催化剂Pd纳米粒子尺寸在1.5~2.5 nm之间,含量为1.5%.催化实验表明,Pd/MIL-101能高效催化吲哚C_2位芳基化,对于活性较差的溴代芳烃,也能得到中等以上的收率,催化剂循环5次后仍能保持较高的反应活性,发展了吲哚C_2位衍生物的简单、高效的合成方法.