基于醛或酮基咔唑超交联多孔聚合物的合成、表征与气体吸附性能

设计合成了醛基或酮基功能化的咔唑9-(4-联苯)-3-甲醛基咔唑(CM-2)、9-(4-联苯)-4-乙酮基咔唑(CM-3)和9-(4-联苯)-2,6-二氟-3-乙酮基咔唑(CM-4).分别以CM-2,CM-3和CM-4为单体,以FeCl_3为催化剂,采用一步法制备了超交联多孔聚咔唑:聚[9-(4-联苯)-3-甲醛基咔唑](HPP-2)、聚[9-(4-联苯)-4-乙酮基咔唑](HPP-3)和聚[9-(4-联苯)-2,6-二氟-3-乙酮基咔唑](HPP-4).反应中间体和聚咔唑的结构由核磁共振波谱(~1H NMR,~(13)C NMR)、魔角旋转交叉固体核磁共振波谱(~(13)C CP/MAS NMR)、红外光谱(IR)和质谱(MS)进行表征,研究了聚咔唑的热稳定性及气体(氮气、二氧化碳和甲烷)吸附性能.结果表明,3种聚咔唑在400℃左右开始分解,450~550℃出现明显失重,然后逐渐趋于平缓,800℃时的热失重均小于25%,表明材料有很好的热稳定性;HPP-2,HPP-3和HPP-4的BET比表面积分别为330,420和660 m~2/g,孔径分别为0.98,0.96和1.07 nm,对二氧化碳的吸附质量分数分别为6.90%,8.30%和9.80%,对甲烷的吸附质量分数分别为1.10%,1.30%和1.60%,表明所得聚合物的孔主要为微孔,且对二氧化碳和甲烷气体有良好的吸附能力.     

富勒烯C60-多芳胺类衍生物选择性加成反应的研究

多芳胺是良好的电子给体,富勒烯C60作为电子受体的光诱导分子内和分子间电荷转移现象[1,2]引起人们普遍关注,尤其是设计合成长寿命电荷分离态的富勒烯C60-多芳胺基类衍生物研究[3,4]是热点课题之一.由于聚吡咯/聚芳胺的氧化还原电位较低[5],我们设想包含吡咯/芳胺给体的富勒烯C60衍生物能延长电荷分离态的寿命.本文用1,3-偶极环加成反应[6]对富勒烯C60与多芳胺化合物的选择性加成反应进行了研究,在不同条件下得到了单加成产物和三加成产物,用FAB-MS,UV-vis,IR,1H NMR,13C NMR,HPLC等方法确定了其分子结构.并且利用半经验AM1量子化学方法在理论上研究了它们的优化构型(如图1)、电子结构,结果表明,富勒烯C60-多芳胺基类衍生物的前沿轨道主要由富勒烯C60部分决定,富勒烯C60母体与功能化基团三苯胺基之间存在较强的分子内电荷转移,这为富勒烯C60衍生物作为光电分子器件材料的应用提供了理论和实验依据.     

1,4-二[(9-苯基)-9H-3-咔唑基)]苯的合成及其光电性能

以对二溴苯和(9-苯基)-9H-3-咔唑硼酸为原料,通过Suzuki偶联反应合成了一种新型含咔唑磷光主体材料——1,4-二[(9-苯基)-9H-3-咔唑基)]苯(1),其结构经1H NMR,13C NMR和IR表征。UV,荧光光谱和循环伏安法的光电性能研究结果表明,1具有咔唑基团的紫外-可见吸收和荧光特性,与4,4-二(9-咔唑)联苯相比,最低空轨道的能级降低。     

含咔唑和偶氮苯的乙炔衍生物的合成

采用Sonagashira偶联反应和N-烷基化反应合成了含有咔唑和偶氮苯的乙炔衍生物:3-乙炔基-9-(4-[4-(硝基)苯基偶氮苯]氧)亚丁基咔唑3.其结构通过IR,1H NMR,13C NMR,元素分析和X-射线单晶衍射法测定.标题化合物属单斜晶系,P21/c空间群;a=9.238(3),b=28.240(8),c...     

N-甲基-2-(4''-N-乙基咔唑基)-[60]富勒烯吡咯烷及其衍生物的合成, 电荷分离态特征

通过1,3-偶极环加成方法在微波照射下合成了N-甲基-2-(4'-N-乙基咔唑基)-富勒烯吡咯烷(C₆₀-Cz)和N-甲基-2- (4'-N,N-二苯基氨基)-富勒烯吡咯烷(C₆₀-TPA), 用质谱, ¹H NMR, IR等对其结构进行了表征. 用激光光解时间分辨瞬态谱研究了N-甲基-2-(4'-N-乙基咔唑基)-富勒烯吡咯烷的分子内电荷转移过程, 在近红外区观测到了长寿命电荷分离态C₆₀^•--C_Z^•+的存在, 其寿命为0.28 μs. 运用Gaussian 98量子化学程序包, 利用密度泛函的方法对N-甲基-2-(4'-N,N-二苯基氨基)-富勒烯吡咯烷几何构型进行了优化, 并在优化基础上用ZINDO方法计算了化合物C₆₀-TPA的电子光谱, 计算结果表明, 光谱吸收峰在440 nm, 与实验值433 nm基本一致.     

富勒烯(C60/C70)与N,N,N',N'一四-(对甲苯基)-4,4'-二胺-1,1'-二苯硒醚(TPDASe)间光诱导电子转移过程的激光光解研究

富勒烯(C60/Z70)与N,N,N',N'-四-(对甲苯基)-4,4'-二胺-1,1'-二苯硒醚(TPDASe)间在激光光诱导条件下,发生了分子间的电子转移过程.在可见-近红外区(600～1200mm),观测到了TPDASe阳离子自由基、富勒烯(C60/C70)激发三线态和阴离子自由基,在苯腈溶液中,观测瞬态谱测定了电子从TPDASe转移到富勒烯(C60/C70)激发三线态的量子转化产率(ΦT et)和电子转移常数(Ket).     

C60富勒醇、C70富勒醇的激光光解研究

在248 nm激光作用下,与通常富勒烯衍生物(如C60(C4H6O),C60(C3H7N),C60[C(COOEt)2]x)在溶液中光解常产生激发三重态不同,富勒烯水溶性衍生物C60(C70)富勒醇[C60(OH)n,C70(OH)m],能被248 nm激光单光子电离.以KI溶液为参照,在室温下(大约15℃)测出其水合电子的量子产额(Φe-)分别为0.08,0.11.通过激光光解与SO4ˉ的氧化,确定了C60富勒醇阳离子自由基或中性自由基的存在并且观察到C70富勒醇阳离子自由基的瞬态吸收峰.     

2个含咔唑基团β-二酮的合成与表征

以咔唑和联苯为原料合成了2个含咔唑基团的新型β-二酮,并用1H NMR、13C NMR、MS、元素分析、热分析、紫外可见吸收光谱及荧光光谱等测试技术进行了表征。 2种β-二酮具有较高的热稳定性,5%失重温度（ΔT5%）分别为319和356 ℃,荧光发射位于蓝光区,最大发射峰为443和455 nm。     

N-甲基-2-{N-乙基-6-[2-(8-甲氧基喹啉基)乙烯基]咔唑基}富勒烯 吡咯烷的合成、电化学性质与双光子吸收特性

设计合成了N-甲基-2-{N-乙基-6-[2-(8-甲氧基喹啉基)乙烯基]咔唑基}富勒烯吡咯烷(6). 产物通过FT-IR, UV, 1H NMR, 13C NMR, MS等对其结构进行表征; 用循环伏安法测定了化合物6的电化学性质. 结果表明, 与参比化合物C60相比还原电位发生负移; 通过Z-扫描方法研究了化合物6的双光子吸收特性, 测得双光子吸收截面积可达62.58 GM. 运用Gaussian 03 量子化学程序包, 采用B3LYP密度泛函(DFT)的方法, 在3-21G(d)水平上对分子的几何构型进行了优化, 预测了化合物6的电化学性质, 与实验结果基本一致.     

4,5-二苯基-2-(9-苯基-9H-3-咔唑基)-1H-咪唑的合成及其性能

以联苯甲酰、对溴苯甲醛和乙酸铵为原料，经缩合反应制得2-(4-溴苯基)-4,5-二苯基咪唑(1); 1与N-苯基-3-咔唑硼酸经Suzuki偶联反应合成了一种具有D-π-A结构的新型咪唑衍生物4,5-苯基-2-(9-苯基-9H-3-咔唑基)-1H-咪唑(2），其结构经¹H NMR, ¹³C NMR, IR和MS(EI)表征。采用FL, UV-Vis，循环伏安法（CV）和理论计算对2的光电性能进行了研究。结果表明：2的最大吸收波长为302 nm和326 nm，荧光发射波长为395 nm和412 nm, HOMO和LUMO轨道能级分别为5.35 eV和2.14 eV。     

Thermally stable perfluoroalkylfullerenes with the skew-pentagonal-pyramid pattern: C60(C2F5)4O, C60(CF3)4O, and C60(CF3)6

Reaction of C(60) with CF(3)I at 550 degrees C, which is known to produce a single isomer of C(60)(CF(3))(2,4,6) and multiple isomers of C(60)(CF(3))(8,10), has now been found to produce an isomer of C(60)(CF(3))(6) with the C(s)-C(60)X(6) skew-pentagonal-pyramid (SPP) addition pattern and an epoxide with the C(s)-C(60)X(4)O variation of the SPP addition pattern, C(s)-C(60)(CF(3))(4)O. The structurally similar epoxide C(s)-C(60)(C(2)F(5))(4)O is one of the products of the reaction of C(60) with C(2)F(5)I at 430 degrees C. The three compounds have been characterized by mass spectrometry, DFT quantum chemical calculations, Raman, visible, and (19)F NMR spectroscopy, and, in the case of the two epoxides, single-crystal X-ray diffraction. The compound C(s)-C(60)(CF(3))(6) is the first [60]fullerene derivative with adjacent R(f) groups that are sufficiently sterically hindered to cause the (DFT-predicted) lengthening of the cage (CF(3))C-C(CF(3)) bond to 1.60 A as well as to give rise to a rare, non-fast-exchange-limit (19)F NMR spectrum at 20 degrees C. The compounds C(s)-C(60)(CF(3))(4)O and C(s)-C(60)(C(2)F(5))(4)O are the first poly(perfluoroalkyl)fullerene derivatives with a non-fluorine-containing exohedral substituent and the first fullerene epoxides known to be stable at elevated temperatures. All three compounds demonstrate that the SPP addition pattern is at least kinetically stable, if not thermodynamically stable, at temperatures exceeding 400 degrees C. The high-temperature synthesis of the two epoxides also indicates that perfluoroalkyl substituents can enhance the thermal stability of fullerene derivatives with other substituents.     

Synthesis, characterization, and theoretical study of stable isomers of C70(CF3)n (n = 2, 4, 6, 8, 10)

Reaction of C70 with ten equivalents of silver(I) trifluoroacetate at 320-340 degrees C followed by fractional sublimation at 420-540 degrees C and HPLC processing led to the isolation of a single abundant isomer of C70(CF3)n for n = 2, 4, 6, and 10, and two abundant isomers of C70(CF3)8. These six compounds were characterized by using matrix-assisted laser desorption ionization (MALDI) mass spectrometry, 2D-COSY and/or 1D 19F NMR spectroscopy, and quantum-chemical calculations at the density functional theory (DFT) level. Some were also characterized by Raman spectroscopy. The addition patterns for the isolated compounds were unambiguously found to be C1-7,24-C70(CF3)2, C1-7,24,44,47-C70(CF3)4, C2-1,4,11,19,31,41-C70(CF3)6, Cs-1,4,11,19,31,41,51,64-C70(CF3)8, C2-1,4,11,19,31,41,51,60-C70(CF3)8, and C1-1,4,10,19,25,41,49,60,66,69-C70(CF3)10 (IUPAC numbering). Except for the last compound, which is identical to the recently reported, crystallographically characterized C70(CF3)10 derivative prepared by a different synthetic route, these compounds have not previously been shown to have the indicated addition patterns. The largest relative yield under an optimized set of reaction conditions was for the Cs isomer of C70(CF3)8 (ca. 30 mol % of the sublimed mixture of products based on HPLC integration). The results demonstrate that thermally stable C70(CF3)n isomers tend to have their CF3 groups arranged on isolated para-C6(CF3)2 hexagons and/or on a ribbon of edge-sharing meta- and/or para-C6(CF3)2 hexagons. For Cs- and C2-C70(CF3)8 and for C2-C70(CF3)6, the ribbons straddle the C70 equatorial belt; for C1-C70(CF3)4, the para-meta-para ribbon includes three polar hexagons; for C1-7,24-C70(CF3)2, the para-C6(CF3)2 hexagon includes one of the carbon atoms on a C70 polar pentagon. The 10.3-16.2 Hz 7JF,F NMR coupling constants for the end-of-ribbon CF3 groups, which are always para to their nearest-neighbor CF3 group, are consistent with through-space Fermi-contact interactions between the fluorine atoms of proximate, rapidly rotating CF3 groups.     

New Ruthenium Complexes of Fullerene C60＆C70

The new complexes[Ru(NO)(PPh3)]2(η^2-Cm)(m=60 1 or 70 2)have been prepared by heating a solution of C60(or C70)with[Ru(NO)2(PPh3)2]in toluene.They have been characterized by elemental analysis,IR,UV/VIS,XPS,^13C and ^13P NMR spectroscopy.The photovaltaic effect for the new compounds has been studied.     

Synthesis, structure, and 19F NMR spectra of 1,3,7,10,14,17,23,28,31,40-C60(CF3)10

A significant improvement in the selectivity of fullerene trifluoromethylation reactions was achieved. Reaction of trifluoroiodomethane with [60]fullerene at 460 degrees C and [70]fullerene at 470 degrees C in a flow reactor led to isolation of cold-zone-condensed mixtures of C60(CF3)n and C70(CF3)n compounds with narrow composition ranges: 6 < or = n < or = 12 for C(60)(CF3)n and 8 < or = n < or = 14 for C70(CF3)n. The predominant products in the C(60) reaction, an estimated 40+ mol % of the cold-zone condensate, were three isomers of C60(CF3)10. Two of these were purified by two-stage HPLC to 80+% isomeric purity. The third isomer was purified by three-stage HPLC to 95% isomeric purity. Thirteen milligrams of this orange-brown compound was isolated (5% overall yield based on C60, and its C1-symmetric structure was determined to be 1,3,7,10,14,17,23,28,31,40-C60(CF3)10 by X-ray crystallography. The CF3 groups are either meta or para to one another on a p-m-p-p-p-m-p-m-p ribbon of edge-sharing C6(CF3)2 hexagons (each pair of adjacent hexagons shares a common CF3 group). The selectivity of the C70 reaction was even higher. The predominant product was a single C70(CF3)10 isomer representing >40 mol % of the cold-zone condensate. Single-stage HPLC led to the isolation of 12 mg of this brown compound in 95% isomeric purity (27% overall yield based on converted C70. The new compounds were characterized by EI or S(8)-MALDI mass spectrometry and 2D-COSY 19F NMR spectroscopy. The NMR data demonstrate that through-space coupling via direct overlap of fluorine orbitals is the predominant contribution to J(FF) values in these and most other fullerene(CF3)n compounds.     

C3v-symmetrical tribenzotriquinacenes as hosts for C60 and C70 in solution and in the solid state

Various tribenzotriquinacenes (TBTQs), most of which incorporate six functional groups at the periphery of their C3v-symmetrical, rigid and convex-concave molecular framework, have been studied with respect to their ability to form supramolecular complexes with the C60 and C70 fullerenes, either in the solid state or in solution. The hexabromo derivative Br6-TBTQ was cocrystallized with C60 as [Br6-TBTQ相似文献   

Preparation and NMR characterization of C70H10: cutting a fullerene pi-system in half

Three isomers of C70H10 were prepared by Zn(Cu) reduction of C70. Three chromatographic bands were identified as C70H10 species by MALDI-FT mass spectrometry, and these compounds were isolated by repeated HPLC treatments. The major isomer (2) was characterized by 1H and 13C NMR, while the minor isomers 3-4 were isolated in such small quantities that only 1H NMR analysis was possible. 1H-coupled and 1H-decoupled 13C NMR of 2 established a 7,8,19,26,33,37,45,49,53,63-substitution pattern. This assignment was confirmed by HMBC and DFQ-COSY experiments. This structure is completely reasonable, as we found that 2 results exclusively from reduction of the 7,19,23,27,33,37,44,53-C70H8 that is formed in the course of the Zn(Cu) reduction of C70.     

Sonochemical Degradation of Polychlorinated Biphenyls in Aqueous Solution

Ultrasonic waves in a liquid induce the formation of cavitation bubbles. Submitted to an oscillating pressure field, cavities filled with vapor and dissolved gas pulsate, grow and implode violently when they reach a critical resonant size. According to the 慼ot spot?theory, extremely high temperature and pressure are produced during the collapse of cavitation bubbles1. Under these extreme conditions, the molecules vaporized in the bubbles as well as in the surrounding condensed layer could …     

Fullerenes as a tert-butylperoxy radical trap,metal catalyzed reaction of tert-butyl hydroperoxide with fullerenes,and formation of the first fullerene mixed peroxides C(60)(O)(OO(t)Bu)(4) and C(70)(OO(Bu)(10)

tert-Butylperoxy radicals generated by TBHP and Ru(PPh3)3Cl2 or other catalysts adds to C60 and C70 to form stable multiadducts, C60(O)(OOtBu)4 and C70(OOtBu)10. The four tert-butylperoxy groups in the C60 mixed peroxide are located around a pentagon, and the epoxy O occupies the remaining 6,6-bond connected to the same pentagon. The C70 decaadduct shows an unprecedented C2 symmetry with the 10 tert-butylperoxy groups added around the central part of C70 by consecutive 1,4-addition. The compounds are fully characterized by spectroscopic data.     

Inclusion properties of 3-fluoromesotetraphenylporphyrin with C60 and C70

To improve the selectivity ratio of C70 over C60, a new designer molecule, viz., 3-fluoromesotetraphenylporphyrin (1) has been reported in the present investigations. Fluorescence studies reveal that the Q-absorption band of 1 gets sufficient quenching effect upon addition of both C60 and C70. Binding constants (K) of the C60/1 and C70/1 complexes are estimated to be 580 and 10,800 dm3 mol(-1), respectively. Thus, K(C70)/K(C60) is approximately 19 which is very large and even comparable with other macrocyclic host molecules like calix[5]arene, azacalix[m]arene[n]pyridine, cyclotriveratrylenophane and calixarene bisporphyrin. 1H NMR chemical shift measurements show that the -NH- proton of 1 suffers more shifts in presence of C70 compared to C60. This finding also offers a good support in favor of high K value for C70/1 complex as well as large selectivity ratio of C70 over C60.     

Thermodynamic rearrangement synthesis and NMR structures of C1, C3, and T isomers of C60H36

The structures of three C60H36 isomers, produced by high-temperature transfer hydrogenation of C(60) in a 9,10-dihydroanthracene melt, was accomplished by 2D (1)H-detected NMR experiments, recorded at 800 MHz. The unsymmetrical C(1) isomer is found to be the most abundant one (60-70%), followed by the C(3) isomer (25-30%) and the least abundant T isomer (2-5%). All three isomers are closely related in structure and have three vicinal hydrogens located on each of the 12 pentagons. Facile hydrogen migration on the fullerene surface during annealing at elevated temperatures is believed to be responsible for the preferential formation of these thermodynamically most stable C60H36 isomers. This hypothesis was further supported by thermal conversion of C60H36 isomers to a single C(3v) isomer of C60H18.