化学法修饰碳纳米管

综述了化学法修饰碳纳米管表面反应的研究进展,从酸化及其衍生反应、环加成反应、氟化反应、原子转移自由基聚合反应、卡宾加成反应等几种反应入手着重介绍了碳纳米管表面修饰的方法和研究状况。     

碳纳米管内P—Ylide反应的理论研究

碳纳米管空腔不仅可以改变填充到其内部分子的性质,而且对其内部的SN2取代反应有促进或抑制作用,因而被视为一种新型的“固体溶剂”．本文通过密度泛函理论研究了CH2O和PH3CH2在气相、苯溶液和碳纳米管空腔内的[2＋2]加成反应．结果表明,与气相相比,碳纳米管空腔对于[2＋2]环加成反应影响不大,这是因为所研究的[2＋2]环加成反应中,反应物并不是轴对称的,不同于SN2取代反应的一维线性排列,所以具有较大轴向极化率的碳纳米管对[2＋2]环加成反应影响较小．     

柱后衍生-高效液相色谱-荧光检测法测定面粉中的过氧化苯甲酰

利用过氧化苯甲酰能够在氯化血红素的催化下将底物对羟基苯乙酸氧化成具有荧光的二聚体的性质,建立了柱后衍生-高效液相色谱-荧光检测法测定面粉中过氧化苯甲酰的方法。优化了色谱分离条件和柱后衍生条件,结果表明:催化剂氯化血红素的浓度为8μmol/L,底物对羟基苯乙酸的浓度为80μmol/L,衍生化试剂的pH 10.5,衍生温度为35℃时衍生效率最高。在优化条件下,过氧化苯甲酰的线性范围为0.5～100 mg/L;样品的检出限为1 mg/kg,样品的加标回收率为98.5%～99.5%。本方法与现有的高效液相色谱法相比,检测面粉中过氧化苯甲酰具有抗干扰能力强,灵敏度高。     

碳纳米管的聚合物功能化与结构控制:聚合物接枝碳纳米管

碳纳米管高分子化是发展高性能的聚合物基纳米功能材料的重要研究方向,本文从"grafting-to"和"grafting-from"两种方式对聚合物接枝碳纳米管的最新进展进行了系统综述。"Grafting-to"方法主要包括羧基衍生反应(酰化、酯化)、加成反应(大分子自由基加成、叠氮环加成)和硫醇偶联反应。"Grafting-from"方法包括普通自由基聚合、可控/活性自由基聚合、离子聚合、开环聚合和逐步聚合反应,其中碳纳米管表面引发活性自由基聚合进一步分为原子转移自由基聚合、氮氧稳定自由基聚合和可逆加成-断链转移聚合。此外,本文还简述了碳纳米管自身的聚合反应,并探讨了目前聚合物修饰碳纳米管所面临的问题和今后的发展方向。     

碳纳米管的共价修饰

碳纳米管(carbon nanotubes, CNTs)的溶解性和分散性较差是目前制约其广泛应用及在一些有特殊要求的领域(如生物技术)应用的主要原因之一. 对CNTs进行共价修饰是改善其溶解性和分散性的有效方法之一. 目前CNTs的共价修饰主要通过两类反应来实现: 羧基的衍生反应和直接加成反应. 介绍了基于这两种反应的几种共价修饰方法, 比较了各种修饰方法的优缺点及其对CNTs的溶解性和分散性的改善效果.     

手性铜催化剂的制备及在环丙烷羧酯酯不对称合成中的应用

３类手性配体ｄ－１０－樟脑磺酸及其衍生物，α－（－）－羟蒎酮及其衍生物，又恶唑啉６衍生物分别与铜（Ⅱ）形成手性铜配合物，催化重氮乙酸酯与１，１－二苯乙烯或异丁烯的环丙烷化加成反应，得到光学活性环丙羧酸酯，不对称诱导最高可达９５％ｅ．ｅ．。     

单壁碳纳米管与卤代烷的亲电加成反应

主要考察了以路易斯酸为催化剂,几种卤代烷烃为反应试剂的单壁碳纳米管侧壁的亲电加成反应,并通过傅立叶红外光谱、热失重分析和拉曼光谱验证了实验所得产物。此反应的目的是在单壁碳纳米管的侧壁连上烷基基团以提高其溶解性和分散性,并可使其更好地与聚烯烃相结合从而提高复合材料的性能,因而具有较高的研究和应用价值。     

二茂铁填充的双壁碳纳米管的合成与红外光谱表征

通过气相法将二茂铁填充到双壁碳纳米管的纳米空腔内部, 制备了一种新型纳米杂化材料——二茂铁-双壁碳纳米管. 对这种纳米材料进行了高分辨透射电子显微镜结构分析与傅立叶变换红外光谱表征. 红外光谱研究结果表明, 碳纳米管管壁与内部二茂铁之间存在强的电子相互作用,并伴有电子转移.     

双核铜配合物[Cu~2(OPPh~3)~2(C~6H~5CO~2)~4]的合成、结构和性质

通过金属铜粉和过氧化苯甲酰的氧化加成反应合成了双核铜配合物[Cu~2(OPPh~3)~2(C~6H~5CO~2)~4], 以元素分析、IR、TG、磁性及粉末衍射表征了配合物的结构, 并对其单晶进行了X射线衍射分析。     

乙烯系单体自由基聚合的阻聚效应──XIX．取代哌啶羟胺和二叔丁基羟胺及其稳定自由基对苯乙烯－丙烯腈共聚合的影响

研究了二叔丁基羟胺（ＤＴＢＨＡ），二叔丁基氮氧自由基（ＤＴＢＮＯ），２，２，６，６－四甲基－４－羟基哌啶羟胺（ＴＭＨＰＨＡ）和２，２，６，６－四甲基－４－羟基哌啶－１－氧自由基（ＴＭＨＰＯ）对过氧化苯甲酰（ＢＰＯ）６０℃引发的苯乙烯（Ｍ１）－丙烯腈（Ｍ２）共聚合的阻聚物行为。结果表明，这些阻聚剂对Ｓｔ－ＡＮ共聚均表现良好的阻聚行为，其中氮氧自由基优于相应羟胺。同时观察到Ｓｔ－ＡＮ竞聚率的改变，羟胺     

不同引发剂引发SBS接枝马来酸酐的机理研究

采用FTIR和1 H NMR研究了引发剂过氧化二苯甲酰 (BPO)和偶氮二异丁腈 (AIBN)对聚苯乙烯 聚丁二烯 聚苯乙烯 (SBS)接枝马来酸酐 (MAH)的影响 ,讨论了相应的接枝机理 ,通过丁二烯 (PB)段碳碳双键(CC)随接枝率变化的规律进一步验证了机理 .结果表明 ,BPO与AIBN引发接枝的机理不同 ,BPO可引发PB的双键和烯丙位碳氢键 ,但引发烯丙位的速率比引发双键大 ;当BPO浓度达到一定量时 ,大量烯丙位的引发保护了碳碳双键 ,随BPO浓度的增大 ,碳碳双键的含量先减少后增加 .AIBN不能引发PB段烯丙位的碳氢键 ,只能引发双键接枝     

过氧化二苯甲酰为引发剂用于液态聚硅烷合成聚碳硅烷

以聚二甲基硅烷裂解制备的液态聚硅烷为原料,添加引发剂过氧化二苯甲酰合成聚碳硅烷,使液态聚硅烷合成聚碳硅烷的产率提高了20%~25%.利用FTIR和GPC对反应过程进行跟踪分析,利用元素分析,1H-NMR,13C-NMR,TG-DTA和XRD对产物的组成结构和性能进行了表征,提出了过氧化二苯甲酰对液态聚硅烷合成聚碳硅烷的促进反应机理.结果表明,过氧化二苯甲酰受热分解形成自由基,促进了液态聚硅烷中的Si—Si键断裂重排,同时也引发了小分子硅碳烷中的Si—H和Si—CH3键断裂生成Si—CH2—Si结构,使聚碳硅烷分子量长大,产率提高.同时过氧化二苯甲酰分解产生的苯基和苯甲酰氧基会作为端基或侧基引入到聚碳硅烷分子中,引起产物C、O含量的少许增加.但对聚碳硅烷高温烧结后的陶瓷收率没有显著影响.     

十八醇亲核取代反应修饰溴代多壁碳纳米管

Octadecanol modified multiple-walled carbon nanotubes, with octadecanol covalently bound to the nanotube surface, have been synthesized by bromination of the carbon nanotubes followed by nucleophilic substitution using octadecanol and sodium hydride. Scanning electron microscopy and transmission electron microscopy images show that the morphologies of the nanotubes are largely intact after functionalization. The brominated carbon nanotubes and octadecanol modified carbon nanotubes were characterized using energy-dispersive X-ray spectroscopy, Raman spectroscopy and Fourier transform infrared spectroscopy. The mechanism of nucleophilic substitution was discussed, and it is believed that the reaction occurs with an SN1 mechanism.     

Structural evolution: mechanism of olefin insertion in hydroformylation reaction

Hydroformylation is the transformation of an alkene to an aldehyde via the addition of both hydrogen and carbon monoxide. The final aldehyde has one more carbon atom than the precursor alkene. Two isomeric products can result. The regiochemistry of the hydroformylation reaction is believed to be controlled by the olefin insertion step. A reaction mechanism is usually studied by finding the reactants, products, intermediates, and transition states. Alternatively, a chemical reaction can be studied from the redistribution of the electron density along the reaction path connecting the stationary points. The aim of this work is to describe the reaction mechanism of the insertion process by the structural evolution defined by the changes in the electron density during the reaction.     

A DFT study of the amination of fullerenes and carbon nanotubes: reactivity and curvature

The first principles density functional theory (DFT) approach (GGA-PW91/DNP) was used to study the addition reaction of methylamine to fullerenes C(50) and C(60) or single-walled carbon nanotubes (SWNTs) (5,5) and (10,0). To understand the relationship between reactivity and curvature, various addition sites have been investigated for comparisons. The DFT calculation results showed that the reaction energy of the addition of methylamine onto C(60) or the closed caps of (5,5) and (10,0) is rather low. Moreover, the reaction at a few sites even appears exothermic. However, the reaction on the perfect sidewall of the nanotubes is always endothermic, and the reaction energy is much higher than that on the caps. The energetically preferable addition sites are the carbon atoms located at the vertexes formed with five-, five-, six-membered rings on C(50) or five-, five-, seven-membered rings on defects of nanotubes. The systematic theoretical study revealed that the pyramidalization and pi-orbital misalignment could result in an increased reactivity of these pentagon-pentagon fusion sites. The reactivity depends on the pyramidalization angle, which is a quantitative measurement of the local curvature and strain of the reaction center.     

Copper-catalyzed intramolecular alkene carboetherification: synthesis of fused-ring and bridged-ring tetrahydrofurans

Fused-ring and bridged-ring tetrahydrofuran scaffolds are found in a number of natural products and biologically active compounds. A new copper-catalyzed intramolecular carboetherification of alkenes for the synthesis of bicyclic tetrahydrofurans is reported herein. The reaction involves Cu-catalyzed intramolecular addition of alcohols to unactivated alkenes and subsequent aryl C-H functionalization provides the C-C bond. Mechanistic studies indicate a primary carbon radical intermediate is involved and radical addition to the aryl ring is the likely C-C bond-forming mechanism. Preliminary catalytic enantioselective reactions are promising (up to 75% ee) and provide evidence that copper is involved in the alkene addition step, likely through a cis-oxycupration mechanism. Catalytic enantioselective alkene carboetherification reactions are rare and future development of this new method into a highly enantioselective process is promising. During the course of the mechanistic studies a protocol for alkene hydroetherification was also developed.     

Theoretical study on the mechanism for the addition reaction of SiH(3) with propylene and acetic acid

To explore the reactivities of alkene (-CH=CH(2)) and carboxy (-COOH) group with H-Si under UV irradiation, the addition mechanism for the reactions of SiH(3) radical with propylene and acetic acid was studied by using the B3LYP/6-311++G(d,p) method. Based on the surface energy profiles, the dominant reaction pathways can be established; i.e., SiH(3) adds to the terminal carbon atom of the alkene (-CH=CH(2)) to form an anti-Markovnikov addition product, or adds to the oxygen atom of the carboxy group (-COOH) to form silyl acetate (CH(3)-COOSiH(3)). Because the barrier in the reaction of the carboxy group (39.9 kJ/mol) is much larger than that of alkene (11.97 kJ/mol), we conclude that the reaction of bifunctional molecules (e.g., omega-alkenoic acid) with H-Si under irradiation condition is highly selective; i.e., the alkene group (-CH=CH(2)) reacts with SiH(3) substantially faster than the carboxyl group (-COOH), which agrees well with the experimental results. This provides the possibility of preparing carboxy-terminated monolayers on silicon surface from omega-alkenoic acids via direct photochemical reaction.     

气凝胶催化剂上甲烷裂解制备的碳纳米管结构特征

采用XRD、TGA、SEM、TEM、 Raman光谱等多种表征手段,考察了Al2O3气凝胶催化剂上甲烷裂解生长的碳纳米管的结构特征.制得的碳纳米管形态单一,为管径均匀、管壁光滑的中空纳米管,平均直径在10～20 nm.碳纳米管的比表面积较大,具有较强的抗氧化能力,其结构的长程有序度较石墨低.由碳纳米管的Raman光谱分析可知,碳纳米管存在碳层缺陷和无定形碳.当反应温度升高或甲烷浓度下降时,碳纳米管石墨化程度逐渐提高.     

CVD growth of N-doped carbon nanotubes on silicon substrates and its mechanism

In the present study, we report the chemical vapor deposition (CVD) of nitrogen-doped (N-doped) aligned carbon nanotubes on a silicon (Si) substrate using ferrocene (Fe(C5H5)2) as catalyst and acetonitrile (CH3CN) as the carbon source. The effect of experimental conditions such as temperature, gaseous environment, and substrates on the structure and morphology of N-doped carbon nanotubes arrays is reported. From XPS and EELS data, it was found that the nitrogen content of the nanotubes could be determined over a wide range, from 1.9% to 12%, by adding the addition of hydrogen (H2) to the reaction system. It was also shown by SEM that N-doped carbon nanotube arrays could be produced on Si and SiO2 substrates at suitable temperatures, although at different growth rates. Using these concentrations, it was possible to produce three-dimensional (3D) carbon nanotubes architectures on predetermined Si/SiO2 patterns. The mechanism underlying the effect of nitrogen containing carbon sources on nanotube formation was explored using X-ray photoelectron spectroscopy (XPS).     

Organometallic reagents in organic synthesis—V: An organocuprate conjugate addition—Aldol condensation synthetic procedure for sequential formation of two carbon-carbon bonds

The enolates produced from the conjugate addition reaction of lithium dialkylcuprates with α,β- unsaturated ketones react with aldehydes in the presence of zinc chloride to give overall β-alkyl α-hydroxyalkyl addition to the original alkene. Reaction of these enolates with carbon dioxide and ethyl formate is also reported.