一种可能形成POPs途径的初探-气相苯的氯化反应

用串联质谱碰撞室模拟大气环境研究了持久性有机污染物(POPs)形成过程,实验发现,经离子-分子反应可以生成氯苯类化合物。 以中性苯与酰氯为反应物在离子源进行反应,在苯含量为4×10^-3Pa、酰氯含量为4×10^-4Pa时,氯苯的生成量为5×10^-8Pa,远远高于背底浓度5×10^-9Pa。对氯苯类化合物的形成,大气环境明显优于质谱环境,实验结果表明,在大气中经离子分子反应形成POPs是可能的。     

离子液体的酸性测定及其催化的二苯醚／十二烯烷基化反应

 采用乙腈探针红外光谱法测定了［bmim］Cl／AlCl3类离子液体的酸性．结果表明，乙腈可以区分离子液体的酸类型（Bronsted酸或Lewis酸），同时可以指示离子液体的Lewis酸强度．使用［bmim］Cl／AlCl3类离子液体催化二苯醚与十二烯的烷基化反应，研究了离子液体的酸强度、反应温度和醚烯比对反应的影响，并与AlCl3催化体系进行对比．结果发现，该离子液体对二苯醚与十二烯烷基化反应的催化活性明显高于AlCl3．使用离子液体作催化剂显著提高了烷基化反应的产率，简化了产物的分离与提纯，且对环境友好．当控制反应温度为80℃，原料醚烯摩尔比为7，并采用酸强度适中的离子液体时，目标产物单十二烷基二苯醚的产率接近90％．     

微波辐射下咪唑类离子液体催化安息香缩合反应研究

探讨了微波辐射下四种咪唑类离子液体催化不同取代基芳香醛的安息香缩合反应,并对反应条件进行了优化。结果表明,[Bmim]Im是合成目标产物的良好催化剂,在微波辐射时间5min、反应温度55℃、催化剂用量x([Bmim]Im)=1%、溶剂THF15m L、芳香醛用量5mmol、50%氢氧化钠水溶液0.5m L时,最高产率可达到81%。该方法耗时短、环境友好。在考查的底物中,除高位阻和具有较强p-π共轭效应的2-氯苯甲醛和4-甲氧基苯甲醛没有检测到产物外,其他不同取代芳香醛均得到了相应产物。反应后离子液体可以回收循环使用至少4次。     

大气复合污染及灰霾形成中非均相化学过程的作用

城市和区域大气复合污染的特征为污染源排放的一次污染物通过大气中的化学反应生成高浓度的氧化剂(臭氧等)及细颗粒物等二次污染物,它们在静稳天气下积累,导致低能见度的灰霾现象并严重影响人体健康和气候.大气复合污染中同时存在高浓度的一次排放和二次转化的气态及颗粒污染物,这为细颗粒表面非均相反应提供了充足的反应物;而气态污染物在细颗粒表面的非均相反应可改变大气氧化性及颗粒物的化学组分、物化性质和光学性质,从而可能对大气复合污染和灰霾的形成起到促进的作用.利用漫反射红外傅里叶变换光谱和单颗粒显微拉曼原位在线技术,我们对大气气态污染物NO2、SO2、O3、甲醛在CaCO3、高岭石、蒙脱石、NaCl、海盐、Al2O3和TiO2等大气主要颗粒物表面的反应进行了系统的反应动力学和机制研究,我们发现反应主要产物为硫酸盐、硝酸盐或甲酸盐,它们可极大改变颗粒物吸湿性和消光性质.通过分析这些非均相反应的动力学过程,我们识别出NO2-颗粒物-H2O、SO2-颗粒物-O3、有机物/SO2-颗粒物-光照等三元反应体系的协同作用机制,这些协同机制对于阐明大气复合污染及灰霾形成的反馈机制和非线性过程提供了实验证据和理论依据.     

酸性离子液体催化的异丁烷/丁烯烷基化反应研究

以一系列酸性离子液体作为催化剂,考察了异丁烷/丁烯在不同离子液体中催化异丁烷与丁烯的烷基化反应,研究了离子液体在进行酸性和阴阳离子调整后对烷基化反应的影响.其中[MBSIM]OTf类离子液体催化所得目的产物三甲基戊烷含量最高可达69.8%,该类催化体系重复使用8次,催化性能没有明显下降.     

大气挥发性有机物实时在线监测的双极性质子转移反应质谱仪研制

大气中挥发性有机物(VOCs)能参与光化学反应,导致臭氧和气溶胶等二次污染物的产生,实时精准地监测VOCs对于大气污染成因研究具有重要意义。在质子转移反应质谱(PTR-MS)研究基础上,本工作研制一套用于大气VOCs实时在线监测的双极性质子转移反应质谱仪(Dipolar proton transfer reaction mass spectrometer,DP-PTR-MS)。相比单一反应离子H_3O~+的常规PTR-MS,DP-PTR-MS中有正负3种反应离子(H_3O~+、OH~-、(CH_3)_2COH~+),可根据实际检测需要选择切换,提高定性能力,并有效扩展检测范围。其中,H_3O~+反应离子用于检测质子亲和势大于H_2O的VOCs;OH~-反应离子可与H_3O~+反应离子配合识别VOCs,还可用于检测CO_2等无机物;(CH_3)_2COH~+反应离子可在排除干扰的情况下准确检测NH_3。利用6种标准气体测定DP-PTR-MS检出限和灵敏度,结果表明,DP-PTR-MS对甲苯的检出限为7×10~(-12)(V/V),对氨气的灵敏度为126.0 cps/10~(-9)(V/V)。利用DP-PTR-MS对合肥市区大气VOCs开展连续78h实时在线监测验证实验,结果表明,DP-PTR-MS可对大气中10~(-12)(V/V)量级VOCs进行长期实时在线监测,可作为大气污染成因研究和痕量VOCs排放监测的重要工具。     

4-氯苯乙醇的合成

以4-氯苯乙酸为起始原料,耦合酯化和还原反应合成了4-氯苯乙醇(1),其结构经1H NMR和MS表征。较适宜的反应条件为:4-氯苯乙酸30 mmol,无水乙醇120 mmol,n(4-氯苯乙酸)∶n(SOCl2)∶n(NaBH4)=1.0∶0.5∶1.6,于室温反应3 h完成酯化反应,产物不经分离直接于75℃反应5 h完成还原反应,1收率高于95%,含量大于99%。     

喜树碱环磷酸酯前药的合成研究

为了提高抗肿瘤药物喜树碱的靶向作用,设计并合成了一种喜树碱的环磷酸酯前药。以间氯苯乙酮为起始原料,经过缩合、还原反应,制备了1-间氯苯基-1,3-丙二醇(2),研究了反应温度对缩合反应的影响。将其与对硝基苯二氯磷酸酯反应合成了制备环磷酸酯前药的重要中间体1-间氯苯基-1,3-丙基环磷酸酯(3),再以10-羟基喜树碱为底物,与中间体3合成了目标化合物喜树碱环磷酸酯前药(4)。探讨了两种催化剂对目标产物喜树碱环磷酸酯前药合成反应的影响,结果表明,叔丁基氯化镁催化效果较好,反应时间缩短到24 h,产物收率42.5%。中间体及产物结构经~1H NMR表征。     

季铵盐型离子液体中全氟烷基磺酰亚胺盐催化的芳烃硝化反应

全氟烷基磺酰亚胺盐与季铵型离子液体（Cu(N(C4F9SO2)2)2/[N4446][NTf2] 或 In(NTf2)3/[N4446][NTf2]）组成的新催化体系,可以很好的催化芳香族化合物的硝化反应。以氯苯的硝化为例,用硝酸和醋酸酐混合物为硝化试剂,在2mol%的Cu(N(C4F9SO2)2)2或In(NTf2)3催化剂催化下,室温下反应10分钟,氯苯的转化率就可分别达到87.6% 和 90.6%,反应产物的邻/对位比为4.3和4.8。并且这种催化剂与离子液体组成的催化体系很容易被回收,并可以连续使用5次以上。     

Cr(Ⅵ)-氯代苯酚共存污染体系中的光反应与光催化反应研究

Cr(Ⅵ)-4CP(4-氯苯酚)共存污染体系中Cr(Ⅵ)离子的紫外光致还原主要是由于Cr(Ⅵ)与4CP光解产物之间的氧化还原反应而引起的。Cr(Ⅵ)离子还原受光强和体系酸度影响较大,还原速率呈零级反应。随体系pH值增大,Cr(Ⅵ)离子还原速率下降。中性条件下,光反应结束后有沉淀产物生成,这对于采用光化学方法消除环境污染提供了很有意义的结果。4CP存在对Cr(Ⅵ)离子在TiO₂表面的暗态吸附没有影响。Cr(Ⅵ)-4CP-TiO₂体系中Cr(Ⅵ)离子的紫外光致还原主要包括了两种反应:Cr(Ⅵ)与4CP之间的均相反应以及Cr(Ⅵ)离子在TiO₂表面的光催化还原反应。一定波长紫外光下,排除Cr(Ⅵ)-4CP-TiO₂体系中的均相反应,使得4CP对Cr(Ⅵ)离子光催化还原反应的促进作用得以证实。     

Collision-induced oxygen addition to chloroaromatic compounds

The reactions of chloroaromatic radical anions with oxygen were studied with a triple quadrupole mass spectrometer. Two chlorobenzenes and eight polychlorinated biphenyls were analyzed by gas chromatography-tandem mass spectrometry under negative ion chemical ionization. The molecular radical anions were selected with the first quadrupole and reacted with oxygen in the collision cell. Under these conditions, [M+O ? Cl] ions were obtained with intensities similar to those of the transmitted precursor ions. This dechlorination reaction was not affected by a detectable chlorine isotope effect. The intensities of the [M+O ? Cl] ions vary with the nature of the chloroaromatic compounds and with the oxygen pressure and collision energy. Charge transfer reactions are also observed, and the relative amount of O ₂ ^?. produced is controlled by the relative electron affinity of the organochlorine. At high collision energies, collision-induced fragmentation of the molecular ion competes for the production of Cl^?.     

HNC/HCN ratio in acetonitrile, formamide, and BrCN discharge

Time-resolved Fourier transform (FT) spectrometry was used to study the dynamics of radical reactions forming the HCN and HNC isomers in pulsed glow discharges through vapors of BrCN, acetonitrile (CH(3)CN), and formamide (HCONH(2)). Stable gaseous products of discharge chemistry were analyzed by selected ion flow tube mass spectrometry (SIFT-MS). Ratios of concentrations of the HNC/HCN isomers obtained using known transition dipole moments of rovibrational cold bands v(1) were found to be in the range 2.2-3%. A kinetic model was used to assess the roles the radical chemistry and ion chemistry play in the formation of these two isomers. Exclusion of the radical reactions from the model resulted in a value of the HNC/HCN ratio 2 orders of magnitude lower than the experimental results, thus confirming their dominant role. The major process responsible for the formation of the HNC isomer is the reaction of the HCN isomer with the H atoms. The rate constant determined using the kinetic model from the present data for this reaction is 1.13 (±0.2) × 10(-13) cm(3) s(-1).     

Effect of protonation and deprotonation on the gas-phase reactivity of fluorinated 1,2,4-triazines

Positive and negative electrospray mass spectrometry (MS), in-time and in-space MS(n) experiments, high-resolution and accurate mass measurements obtained with an Orbitrap, together with density functional theory calculations have been used to study the gas-phase ion chemistry of a series of fluorinated 1,2,4-triazines. As a result of low-energy collision-induced dissociations, occurring in an ion trap and in a triple quadrupole, their protonated and deprotonated molecules show interesting features depending on the nature and structure of the precursor ions. The occurrence of elimination/hydration reactions produced by positive ions in the ion trap is noteworthy. Decompositions of deprotonated molecules, initiated by elimination of a hydroxyl radical from [M-H](-), are dominated by radical anions. Theoretical calculations have allowed us to obtain information on atom sites involved in the protonation and deprotonation reactions.     

Generation of ion-bound solvent clusters as reactant ions in dopant-assisted APPI and APLI

We provide experimental and theoretical evidence that the primary ionization process in the dopant-assisted varieties of the atmospheric pressure ionization methods atmospheric pressure photoionization and atmospheric pressure laser ionization in typical liquid chromatography–mass spectrometry settings is—as suggested in the literature—dopant radical cation formation. However, instead of direct dopant radical cation–analyte interaction—the broadly accepted subsequent step in the reaction cascade leading to protonated analyte molecules—rapid thermal equilibration with ion source background water or liquid chromatography solvents through dopant ion–molecule cluster formation occurs. Fast intracluster chemistry then leads to almost instantaneous proton-bound water/solvent cluster generation. These clusters interact either directly with analytes by ligand switching or association reactions, respectively, or further downstream in the intermediate-pressure regions in the ion transfer stages of the mass spectrometer via electrical-field-driven collisional decomposition reactions finally leading to the predominantly observed bare protonated analyte molecules [M?+?H]⁺.     

Electron transfer dissociation of peptide anions

Ion/ion reactions of multiply deprotonated peptide anions with xenon radical cations result in electron abstraction to generate charge-reduced peptide anions containing a free-radical site. Peptide backbone cleavage then occurs by hydrogen radical abstraction from a backbone amide N to facilitate cleavage of the adjacent C-C bond, thereby producing a- and x-type product ions. Introduction of free-radical sites to multiply charged peptides allows access to new fragmentation pathways that are otherwise too costly (e. g., lowers activation energies). Further, ion/ion chemistry, namely electron transfer reactions, presents a rapid and efficient means of generating odd-electron multiply charged peptides; these reactions can be used for studying gas-phase chemistries and for peptide sequence analysis.     

Evolution of instrumentation for the study of gas-phase ion/ion chemistry via mass spectrometry

The scope of gas-phase ion/ion chemistry accessible to mass spectrometry is largely defined by the available tools. Due to the development of novel instrumentation, a wide range of reaction phenomenologies has been noted, many of which have been studied extensively and exploited for analytical applications. This perspective presents the development of mass spectrometry-based instrumentation for the study of the gas-phase ion/ion chemistry in which at least one of the reactants is multiply charged. The instrument evolution is presented within the context of three essential elements required for any ion/ion reaction study: the ionization source(s), the reaction vessel or environment, and the mass analyzer. Ionization source arrangements have included source combinations that allow for reactions between multiply charged ions of one polarity and singly charged ions of opposite polarity, arrangements that enable the study of reactions of multiply charged ions of opposite polarity and, most recently, arrangements that allow for ion formation from more than two ion sources. Gas-phase ion/ion reaction studies have been performed at near atmospheric pressure in flow reactor designs and within electrodynamic ion traps operated in the mTorr range. With ion trap as a reaction vessel, ionization and reaction processes can be independently optimized and ion/ion reactions can be implemented within the context of MSn experiments. Spatial separation of the reaction vessel from the mass analyzer allows for the use of any form of mass analysis in conjunction with ion/ion reactions. Time-of-flight mass analysis, for example, has provided significant improvements in mass analysis figures of merit relative to mass filters and ion traps.     

Reactions induced by the γ-hydrogen shift in the molecular ion of 1-nitropropane

It is shown that the γ- or 1,5-hydrogen shift in the molecular ion of 1-nitropropane leads to three primary fragmentation reactions. They are the loss of a hydroxyl radical, a molecule of ethylene and a molecule of nitric oxide. The structures and chemistry of the resulting ions have been investigated by a series of experiments including deuterium labelling, spontaneous and collisionally induced dissociations and accurate mass measurements.     

Carbon clusters

Some of the most significant discoveries and achievements concerning the mass spectra and gas phase ion chemistry of carbon clusters are reviewed. These include (1) nanosecond and femtosecond laser ionizations; (2) ion structures through ion/molecule reactions, ion chromatography, and computational methods; (3) carbon cluster cooling through radiative decay, dissociative decay, and thermionic emission; (4) mechanisms and energetics of fragmentation reactions; (5) endohedral fullerenes including recent data on ion beam implantation, and (6) ion chemistry as a function of the fullerene charge state.     

Time-resolved molecular beam mass spectrometry of the initial stage of particle formation in an Ar/He/C2H2 plasma

The temporal evolution of the neutral plasma chemistry products in a capacitively coupled plasma from argon/helium/acetylene is followed via molecular beam mass spectrometry with a time resolution of 100 ms. Several chemistry pathways are resolved. (i) The formation of C2nH2 (n = 2-5) molecules proceeds via the following sequence: the production of highly reactive C2H radicals in electron impact dissociation of C2H2 is followed by C2H induced chain polymerization of C2nH2 (n = 1-4). (ii) CnH4 (n = 4, 5, 6) compounds are detected already at an early stage of the discharge excluding polymerization reactions with C2H radical being responsible for their formation. Instead, vinylidene reactions with acetylene or mutual neutralization reactions of ionic species are proposed as sources of their formation. (iii) Surface reactions are identified as the source of C8H6. The measured hydrocarbon molecules represents possible precursors for negative ion formation via dissociative electron attachment reactions and can hence play a crucial role in particle nucleation. On the basis of the comparison of our data with available experimental and modeling results for acetylene plasmas in the literature, we propose C2nH2 (n > 1) molecules as important precursors for negative ion formation.