树枝状聚酰胺胺负载TEMPO的合成及其催化分子氧氧化醇的性能

以乙二胺和丙烯酸甲酯为原料,经过重复Michael和酯氨解反应,制备出二代(2.0 G)树枝状聚酰胺胺(PAMAM).PAMAM与2,2,6,6-四甲基哌啶酮氮氧自由基经缩合、还原将PAMAM与2,2,6,6-四甲基哌啶氮氧自由基(TEMPO)键连,得到PAMAM负载的TEMPO(PAMAM-TEMPO).采用1H NMR、13C NMR以及FT-IR等手段对中间体及最终产物进行了表征.将PAMAM-TEMPO与CuBr2以及2,2-联吡啶结合构成催化体系,用于分子氧为氧化剂的醇的选择性氧化反应,结果表明该体系对苄基以及烯丙基伯醇的氧化显示出良好的催化活性和选择性.结果还证明,TEMPO的负载使氧化产物醛很容易与催化体系分离,而且催化剂可以循环使用.     

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.     

氮氧自由基TEMPO：选择氧化醇的高效有机小分子催化剂*

醇被氧化为相应的醛或酮是有机合成中重要的官能团转换反应之一。自从Anelli法（TEMPO/NaBr/NaOCl）发现以来,由于所具有的醇被氧化为相应的醛或酮是有机合成中重要的官能团转换反应之一。自从Anelli法（TEMPO/NaBr/NaOCl）发现以来,由于所具有的高活性和高选择性, 有机小分子催化剂2,2,6,6-四甲基哌啶-1-氧自由基(TEMPO)催化醇的氧化反应成为温和条件下醇选择氧化的一个重要方法,并在实验室和工业生产中广泛应用。最近有关TEMPO催化醇氧化反应的研究,主要集中在开发用于分子氧对醇绿色氧化的催化体系和目的在于实现催化剂回收再用的TEMPO固载化研究两个领域上。本文以此为重点,综述了TEMPO催化醇氧化反应的发展和最近研究进展。     

吸附NOx的功能化硅胶用于催化温和条件下醇的选择性氧化

利用接枝方式将2,2,6,6-四甲基哌啶(TEMPO)固载到SPE柱填料硅胶上制备了功能化硅胶,其吸附NO_x应用于催化醇的选择性氧化反应中. 并利用元素分析、红外光谱、N₂吸附-脱附和NO_x程序升温脱附对催化剂进行了考察. 结果表明,所制备催化剂中TEMPO固载量为0.292 mmol/g,NO_x吸附量为0.749 mmol/g; 常温常压下1 mmol芳香醇在0.5g该催化剂作用下进行选择性氧化反应2h,原料转化率和产物选择性均高达99%. 该催化剂提高了醇分子在孔道内部与TEMPO和NO_x接触几率,促进了反应进行,根据反应现象,对该体系催化机理进行了推测.     

2,2,6,6-四甲基哌啶-1-氧自由基促进的钒基催化剂催化苯直接氧化制苯酚

以钒基化合物为催化剂,在TEMPO(2,2,6,6-四甲基哌啶-1-氧自由基)存在下,能形成快速催化分子氧氧化苯制苯酚的催化体系.在反应过程中,由类似芬顿试剂反应过程生成的羟基自由基亲核进攻苯环,形成羟基环己二烯自由基;该羟基氢可在TEMPO存在的催化体系中消除,同时苯环氢可立即转移至氧原子而生成苯酚.在以[(CH3)...     

含环氧基团的聚合物微球固载2,2,6,6-四甲基哌啶氮氧自由基催化剂的制备及其催化分子氧氧化苯甲醇

以甲基丙烯酸缩水甘油酯(GMA)为单体, 以乙二醇二甲基丙烯酸酯(EGDMA)为交联剂, 采用悬浮聚合法制得交联聚甲基丙烯酸缩水甘油酯(CPGMA)微球, 然后以4-羟基-2,2,6,6-四甲基哌啶氮氧自由基(4-OH-TEMPO)为试剂, 使CPGMA微球表面的环氧基团发生开环反应, 从而制得了TEMPO固载化微球TEMPO/CPGMA, 考察了制备条件对固载化反应的影响, 并采用多种方法对微球TEMPO/CPGMA进行了表征. 将微球TEMPO/CPGMA与CuCl组成共催化体系, 用于分子氧氧化苯甲醇, 考察了反应条件对催化体系性能的影响. 结果表明, 以含环氧基团的聚合物微球CPGMA为载体, 通过开环反应, 可成功地实现TEMPO的固载化, 开环反应属S_N2亲核取代反应, 适宜采用溶剂N,N''-二甲基甲酰胺和反应温度85℃. 非均相催化剂TEMPO/CPGMA与助催化剂CuCl构成共催化体系, 在室温、常压O₂条件下可高效地将苯甲醇氧化为苯甲醛, 产物选择性和产率分别为100%和90%. 主催化剂TEMPO与助催化剂CuCl适宜的摩尔比为1:1.2; 主催化剂适宜用量为0.90 g. 此外, TEMPO/CPGMA固体催化剂具有良好的循环使用性能.     

聚合物微球固载的催化剂TEMPO在分子氧氧化环己醇过程中的催化特性

醇氧化为羰基化合物是有机合成工业中最重要的化学转变之一,在实验室研究和精细化工生产中都占有非常重要的地位.使用传统的化学计量强氧化剂(如CrO3, KMnO4, MnO2等),不但成本高及反应条件苛刻,还会产生大量污染环境的废弃物.因此,需要大力发展高效、绿色化的醇转变为羰基化合物的氧化途径.以2,2,6,6-四甲基哌啶氮氧自由基(TEMPO)为催化剂,分子氧为氧化剂,可在温和条件下绿色化地实现醇的氧化转变.该催化氧化作用的实质是TEMPO经过单电子氧化过程转化为相应的氮羰基阳离子,该阳离子是一个具有强氧化性的氧化剂,可将伯醇和仲醇分别快速地、高转化率、高选择性地氧化为对应的醛或酮.然而,目前使用的TEMPO大多为均相催化剂,虽然表现出良好的催化活性和选择性,但反应后难以分离回收,不能再循环使用,严重制约着这一催化体系的发展.本文将TEMPO化学键合在聚合物载体上,在非均相催化剂的作用下,以期实现环已醇的分子氧氧化,将其转变为环已酮.首先采用悬浮聚合法,制备了交联聚甲基丙烯酸缩水甘油酯(CPGMA)微球,该聚合物微球表面含有大量环氧基团,为实现TEMPO的固载化提供了条件.以4-羟基-2,2,6,6-四甲基哌啶氮氧自由基(4-OH-TEMPO)为试剂,使CPGMA微球表面的环氧基团发生开环反应,从而将TEMPO键合于微球表面,制得了固载有TEMPO的聚合物微球TEMPO/CPGMA.将此非均相催化剂与Fe(NO3)3组成共催化体系,应用于分子氧氧化环己醇的催化氧化过程,深入考察了该共催化体系的催化性能,并探索研究了催化氧化机理,考察了主要条件对催化氧化反应的影响.结果表明,共催化体系TEMPO/CPGMA+Fe(NO3)3可以有效地催化分子氧氧化环己醇的氧化过程,将环己醇转化为唯一的产物环己酮,显示出良好的催化选择性.助催化剂Fe(NO3)3化学结构中的Fe3+离子和NO3–离子两种物种均参与催化过程,共同发挥助催化剂的作用,伴随着两种价态铁物种Fe(Ⅱ)与Fe(Ⅲ)的转变以及NO3–与NO2–之间的转变,固载化的氮氧自由基TEMPO不断地转变为氮羰基阳离子,该氧化剂物种使环己醇的氧化反应不断地循环进行.对于共催化体系TEMPO/CPGMA+Fe(NO3)3的使用,适宜的反应条件为TEMPO与Fe(NO3)3的摩尔比为1：1,55°C,通入常压O2.反应35 h,环己酮的转化率可达到44.1%.因此,在温和条件下,使用固载化的TEMPO,有效地实现了环己醇向环己酮的转化.此外,固载化催化剂TEMPO/CPGMA在循环使用过程中表现出良好的重复使用性能.     

功能离子液体催化分子氧氧化醇为醛酮

2,2,6,6-四甲基-N-氧自由基哌啶醇(2,2,6,6-tetramethyl-piperidin-4-ol-N-oxyl,TEMPO)与氯乙酰氯反应生成2-氯乙酸-2,2,6,6-四甲基-1-氧-4-哌啶醇酯,该酯与N-甲基咪唑发生季铵化反应后再与六氟磷酸钾进行离子交换制得2,2,6,6-四甲基-N-氧自由基哌啶醇负载离子液体TEMPO-IL。温和条件下以离子液体1-甲基-3-丁基咪唑六氟磷酸盐(1-butyl-3-methylimidazolium hexafluorophosphate,[bmim]PF6)为溶剂,TEMPO-IL和CuCl为催化剂,分子氧氧化各种醇为相应的醛或酮。研究发现,该氧化体系对苄醇和烯丙醇有较好的氧化效果,65℃下反应10h左右,转化率可达99%,收率可达80%~90%。氧化体系对醛酮有高度的选择性,在实验所采用的条件范围内未检测到有羧酸生成。溶剂和催化剂可循环使用,在苯甲醇的氧化中,溶剂和催化剂循环使用6次,反应转化率和苯甲醛的收率保持不变。     

聚合物微球固载的催化剂TEMPO在分子氧氧化环己醇过程中的催化特性（英文）

醇氧化为羰基化合物是有机合成工业中最重要的化学转变之一,在实验室研究和精细化工生产中都占有非常重要的地位.使用传统的化学计量强氧化剂(如Cr O3,KMnO4,MnO2等),不但成本高及反应条件苛刻,还会产生大量污染环境的废弃物.因此,需要大力发展高效、绿色化的醇转变为羰基化合物的氧化途径.以2,2,6,6-四甲基哌啶氮氧自由基(TEMPO)为催化剂,分子氧为氧化剂,可在温和条件下绿色化地实现醇的氧化转变.该催化氧化作用的实质是TEMPO经过单电子氧化过程转化为相应的氮羰基阳离子,该阳离子是一个具有强氧化性的氧化剂,可将伯醇和仲醇分别快速地、高转化率、高选择性地氧化为对应的醛或酮.然而,目前使用的TEMPO大多为均相催化剂,虽然表现出良好的催化活性和选择性,但反应后难以分离回收,不能再循环使用,严重制约着这一催化体系的发展.本文将TEMPO化学键合在聚合物载体上,在非均相催化剂的作用下,以期实现环已醇的分子氧氧化,将其转变为环已酮.首先采用悬浮聚合法,制备了交联聚甲基丙烯酸缩水甘油酯(CPGMA)微球,该聚合物微球表面含有大量环氧基团,为实现TEMPO的固载化提供了条件.以4-羟基-2,2,6,6-四甲基哌啶氮氧自由基(4-OH-TEMPO)为试剂,使CPGMA微球表面的环氧基团发生开环反应,从而将TEMPO键合于微球表面,制得了固载有TEMPO的聚合物微球TEMPO/CPGMA.将此非均相催化剂与Fe(NO3)3组成共催化体系,应用于分子氧氧化环己醇的催化氧化过程,深入考察了该共催化体系的催化性能,并探索研究了催化氧化机理,考察了主要条件对催化氧化反应的影响.结果表明,共催化体系TEMPO/CPGMA+Fe(NO3)3可以有效地催化分子氧氧化环己醇的氧化过程,将环己醇转化为唯一的产物环己酮,显示出良好的催化选择性.助催化剂Fe(NO3)3化学结构中的Fe3+离子和NO3–离子两种物种均参与催化过程,共同发挥助催化剂的作用,伴随着两种价态铁物种Fe(Ⅱ)与Fe(Ⅲ)的转变以及NO3–与NO2–之间的转变,固载化的氮氧自由基TEMPO不断地转变为氮羰基阳离子,该氧化剂物种使环己醇的氧化反应不断地循环进行.对于共催化体系TEMPO/CPGMA+Fe(NO3)3的使用,适宜的反应条件为TEMPO与Fe(NO3)3的摩尔比为1:1,55°C,通入常压O2.反应35 h,环己酮的转化率可达到44.1%.因此,在温和条件下,使用固载化的TEMPO,有效地实现了环己醇向环己酮的转化.此外,固载化催化剂TEMPO/CPGMA在循环使用过程中表现出良好的重复使用性能.     

CuI/TPA/4-乙酰胺基-TEMPO催化的苄醇与烯丙基醇氧化反应的研究

CuI/TPA(tris(pyridin-2-ylmethyl)amine)/4-乙酰胺基-TEMPO(2,2,6,6-Tetramethylpiperidyl-1-oxyl)催化体系能够在室温下,以氧气作氧化剂,乙腈作溶剂,高效、高选择性地催化一系列苄醇,烯丙基醇和含杂原子伯醇的氧化,且在体系中无需添加任何碱作助催化剂.     

Synthesis and charge/discharge properties of polyacetylenes carrying 2,2,6,6-tetramethyl-1-piperidinoxy radicals

The 2,2,6,6-tetramethyl-1-piperidinoxy (TEMPO)-containing acetylenic monomers HC[triple bond]CC(6)H(3)-p,m-(CONH-4-TEMPO)(2) (1), HC[triple bond]CC(6)H(3)-p,m-(COO-4-TEMPO)(2) (2), (S,S,S,S)-HC[triple bond]CC(6)H(3)-p,m-[CO-NHCH{COO-(4-TEMPO)}CH(2)COO-(4-TEMPO)](2) (3), (S,S)-HC[triple bond]CC(6)H(4)CO-NHCH{COO-(4-TEMPO)}CH(2)COO-(4-TEMPO) (4), HC[triple bond]CC(6)H(4)-p-OCO-4-TEMPO (5), HC[triple bond]CCH(2)C(CH(3))(CH(2)OCO-4-TEMPO)(2) (6), HC[triple bond]CCH(2)NHCO-4-TEMPO (7), and HC[triple bond]CCH(2)OCO-4-TEMPO (8) were polymerized to afford novel polymers containing the TEMPO radical at high densities. Monomers 1, 3-6, and 8 provided polymers with average molecular weights of 10 000-136 500 in 62-99 % yield in the presence of a rhodium catalyst, whereas monomers 2 and 7 gave insoluble polymers in 100 % yield. The formed polymers were thermally stable up to approximately 274 degrees C according to thermogravimetric analysis (TGA). All the TEMPO-containing polymers demonstrated reversible charge/discharge processes, whose discharge capacities were 21.3-108 A h kg(-1). In particular, the capacity of poly(1)-, poly(4)-, and poly(5)-based cells reached 108, 96.3, and 89.3 A h kg(-1), respectively, which practically coincided with their theoretical values.     

Synthesis and reactivity of a transition metal complex containing exclusively TEMPO ligands: Ni(η2-TEMPO)2

The reaction of Ni(COD)(2) with two equivalents of the TEMPO radical at 68 °C affords the 16 e(-) "bow-tie" complex Ni(η(2)-TEMPO)(2), 1, in 78% yield. Compound 1 reacts with tert-butyl isocyanide and phenylacetylene at room temperature to yield the 16 e(-) distorted square planar nickel complexes Ni(η(2)-TEMPO)(η(1)-TEMPO)(CN(t)Bu), 2, and Ni(η(2)-TEMPO)(η(1)-TEMPOH)(CCPh), 4, respectively. The facile reactivity of 1 is aided by the transition of the TEMPO ligand from an η(2) to η(1) binding mode. Complex 4 is an unusual example of hydrogen atom transfer from phenylacetylene to a coordinated TEMPO ligand.     

Pillar[5]arene based conjugated macrocycle polymers with unique photocatalytic selectivity

The development of heterogeneous catalysts with substrate shape, size or electronic constitution selectivity is a huge challenge in photocatalysis. Reported herein is a host-guest interaction strategy to endow photocatalysts with special selectivity. By adjusting the precursors, conjugated macrocycle polymers (CMPs) with pillar[5]arene struts (CMP-1 and CMP-2) and a corresponding non-pillar[5]arene-contained conjugated organic polymer (COP-1) were prepared and the photocatalytic activities toward sulfide derivatives were investigated. The sulfides showed similar conversions when COP-1 was used as a photocatalyst, but exhibited significant differences when it turned to the CMPs. Remarkably, the conversion yield of S-1 achieved near 18 folds over the one of S-2 when CMP-2 was used as a catalyst. Mechanism studies confirmed that the “host-guest” effect of pillar[5]arene struts in CMPs was the main cause of the difference. The present work establishes CMPs as novel heterogeneous photocatalysts with substrate selectivity, and such a method will inspire the researchers concerning preparation of heterogeneous catalysts with excellent selectivity.     

N-O bond homolysis of an iron(II) TEMPO complex yields an iron(III) oxo intermediate

The reaction of TEMPO with the iron(I) synthon PhB(MesIm)(3)Fe(COE) leads to formation of the κ(1)-TEMPO complex PhB(MesIm)(3)Fe(TEMPO). Structural and spectroscopic data establish the complex contains divalent iron bound to a nitroxido anion and is isoelectronic to an iron(II) peroxo complex. Thermolysis of the complex results in N-O bond homolysis, leading to the formation of an iron(III) oxo intermediate. The oxo intermediate is active in oxygen atom transfer reactions and can be trapped by the triphenylmethyl radical to give the iron(II) alkoxo complex PhB(MesIm)(3)Fe(OCPh(3)).     

Gibbs monolayers at the air/water interface: surface partitioning and lateral mobility of an electrochemically active surfactant

Monolayer films of a water-soluble surfactant, 4-octaneamido-2,2,6,6-tetramethyl-1-piperidinyloxy (C8-TEMPO) were investigated at the air/water interface. An electrochemical, horizontal touch method was developed to measure the equilibrium surface concentrations (gamma) of C8TEMPO. The dependence of gamma on the solution concentration followed a Langmuir isotherm and yielded the partition constant K = (2.3+/-0.2) x 10(4) M(-1). These results were verified by surface tension measurements and Brewster angle microscopy. Within experimental error, the same K values were obtained. The lateral diffusion constants vs surface concentration of this molecule were measured by 2D voltammetry. In these experiments, the component of the oxidation current due to C8TEMPO in the bulk of the solution was subtracted from the total measured current to obtain the component due to the lateral surface diffusion. In the ange of mean molecular areas from 120 to 400 A2/molecule, the lateral diffusion constant of C8TEMPO increased from 1.0 x 10(-6) to 1.0 x 10(-5) cm2/s. The latter value is about 2.5 times larger than the C8TEMPO diffusion constant in bulk water. Comparison of the lateral mobilities of C8TEMPO and two longer alkane chain, water-insoluble homologues, C14TEMPO and C18TEMPO, showed no statistically significant differences.     

Single electron transfer (SET) activity of the dialkyl-amido sodium zincate [(TMEDA)·Na(μ-TMP)(μ-tBu)Zn(tBu)] towards TEMPO and chalcone

More usually thought of as a base, the sodium zincate [(TMEDA)·Na(μ-TMP)(μ-(t)Bu)Zn((t)Bu)] 1 can undergo single electron transfer with TEMPO to give [(TMEDA)·Na(μ-TMP)(μ-TEMPO(-))Zn((t)Bu)] 2 and [(TMEDA)·Na(μ-TEMPO(-))(2)Zn((t)Bu)] 3; and with chalcone [PhCOCH=CHPh] gives [{(TMEDA)·Na(μ-TMP)Zn((t)Bu)}(2)(μ-OCPhCH=CHPhCHPhCH=CPh-μ-O)] which contains two chalcone units C-C coupled though their benzylic C atoms.     

A TEMPO-Functionalized Ordered Mesoporous Polymer as a Highly Active and Reusable Organocatalyst

The properties of high stability, periodic porosity, and tunable nature of ordered mesoporous polymers make these materials ideal catalytic nanoreactors. However, their application in organocatalysis has been rarely explored. We report herein for the first time the incorporation of a versatile organocatalyst, 2,2,6,6-tetramethyl-1-piperidinyloxy (TEMPO), into the pores of an FDU-type mesoporous polymer via a pore surface engineering strategy. The resulting FDU-15-TEMPO possesses a highly ordered mesoporous organic framework and enhanced stability, and shows excellent catalytic activity in the selective oxidation of alcohols and aerobic oxidative synthesis of 2-substituted benzoxazoles, benzimidazoles and benzothiazoles. Moreover, the catalyst can be easily recovered and reused for up to 7 consecutive cycles.     

Nitroxyl radicals of the imidazoline series as agents of pseudoliving polymerization of styrene

Radical polymerization of styrene in the presence of 2,2,4,5,5-pentamethyl-2,5-dihydro- Imidazol-1-oxyl, 2,2-diethyl-4,5,5-trimethyl-2,5-dihydroimidazol-1-oxyl, 2,2,5,5-tetramethyl- 4-phenyl-2,5-dihydroimidazol-1-oxyl, 2,2,5-trimethyl-4,5-diphenyl-2,5-dihydroimidazol- 1-oxyl, and 2-methyl-2,3-diphenyl-1,4-diazaspiro[4.5]deca-3-en-1-oxyl was studied. Effect of substituents in the nitroxyl radical and the nature of initiator on the features of “pseudoliving” polymerization and the molecular-weight characteristics of polystyrene synthesized were considered. Nitroxyl radicals of imidazoline series, like TEMPO and its derivatives, allow one to regulate polymerization of styrene and obtain polymers with relatively low values of polydispersity index.     

Controlled radical polymerization of 4-vinylpyridine

2,2,6,6-Tetramethylpiperidine-N-oxyl (TEMPO)-mediated free radical polymerization of 4-vinylpyridine is found to proceed in a “controlled” manner. A linear increase of molecular weight along with an increase in conversion occurs at varying temperatures. Polymerization of styrene with a poly(4-vinylpyridine) block as macromer results in block copolymers with narrow polydispersity. The polymers are characterized by different size exclusion chromatography methods and converted to cationic polyelectrolytes as well as to polysulfo- and polycarbobetaines.     

以2,2′-联吡啶与丙二腈为添加剂的苯乙烯活性自由基聚合的研究

研究了稳定自由基存在下苯乙烯的活性聚合 .发现在 2 ,2′ 联吡啶的存在下 ,苯乙烯聚合的分子量控制效果提高 ,分子量可控 ,分子量分布较窄 .在与丙二腈共同作用时 ,可在 4h内达到 85 %的转化率 ,分子量分布在 1 5以下 ,分子量控制误差在 2 0 %以下 .设计分子量在 1× 10 4 ～ 9× 10 4 的范围内 ,实测分子量和理论分子量相近 .