C4H5N-(NH3)n氢键团簇的多光子电离与从头计算

在355和532nm激光波长下用TOF质谱仪研究了C4H5N-(NH3)n系列氢键团簇体系的多光子电离.实验发现,两波长下除了得到一系列团簇离子外,还观测到一系列质子化产物C4H5N-(NH3)n－H＋.这些质子化产物来自于光电离过程中团簇内部的质子转移反应;系列离子出现反常强度变化,即离子强度较离子明显减小;从头计算结果表明,上述现象是由于中性团簇稳定性的差异造成的.     

甲醇团簇的多光子电离质谱及其从头算

用355 nm激光对脉冲分子束超声膨胀冷却的甲醇分子进行多光子电离, 飞行时间质谱仪观测到除甲醇碎片离子外的质子化甲醇团簇(CH3OH)nH+(n=1-16), 且离子的种类及相对强度与激光相对于脉冲分子束的延时无关, 取决于团簇离子内在结构的稳定性. 结合从头算密度泛函理论, 在B3LYP/6-31G(d)基组水平上优化得到了(CH3OH)n和(CH3OH)nH+(n=1-4)的稳定构型. 振动频谱分析显示, 团簇中最强的红外振动模主要来自氢键H伸缩振动的贡献. 团簇电离后发生于团簇内的质子转移反应也可能与激光电离引起的与氢键有关的振动模激发密切相关.     

C4H5N-(H2O)n氢键团簇的多光子电离与从头计算研究

在355、532nm激光波长下用TOF质谱研究了C4H5N-(H2O)n氢键团簇体系的多光子电离。二波长下均得到一系列C4H5N-(H2O)n+及质子化产物C4H5N-(H2O)nH+。355nm下可能存在双光子共振电离过程,使得该波长下吡咯母体及团簇离子信号较532nm有明显增强。从头计算结果表明质子化产物的质子更可能连接于吡咯环的α-C原子,而不是N原子上,即光电离过程诱发了一个簇内的质子转移反应。在532nm下质子化产物的生成主要来自于一个发生于团簇内部的Penning电离或电荷转移过程。团簇的形成对吡咯光解产物的稳定化作用使得团簇系列C4H4N-(H2O)n+出现反常强度变化。     

应用反射式飞行时间质谱仪研究氨团簇离子解离动力学

用直射式和反射式飞行时间质谱研究了氨分子团簇体系在 355 nm激光下的多光子电离,得到一系列的质子化团簇离子 (NH3)nH+,同时还观察到超价氨团簇离子 (NH3)n H2＋。在反射式飞行时间质谱研究中观测到质子化氨团簇离子在自由飞行过程中的解离现象,表明在该实验条件下生成的质子化氨团簇离子是一些亚稳态团簇离子。对子离子产率的分析,得到质子化团簇离子解离速率常数,从而可以估计亚稳态团簇离子的寿命。团簇尺寸从 n＝3增大到 20,其寿命从 21 ms减小到 120 μs,大约小了两个数量级。解离速率在 n＝5到 6有一个阶跃式上升,这是由于 5个氨组成的质子化团簇离子(NH3)4NH4+ 的结构相对比较稳定。     

1,4-二氧六环和氨分子氢键团簇的从头算

在不同基组水平上,对１,４－二氧六环和氨分子氢键团簇体系进行了从头算分子转道法研究,优化得到中性团簇,离子团簇和碎片离子（质子化团簇离子和非质子化团簇离子）平衡几何构型,研究结果表明：中性团簇最稳定构型为Ｒ－ＨＮ２－ＨＮＮ２（Ｒ：１,４－二氧六环）,离子团簇由于发生质子转移,其构型与中 团簇有较大的淡同,两类碎片离子Ｒ（ＮＨ３）＋和Ｒ（ＮＨ３）Ｈ＾＋与中性团簇Ｒ（ＮＨ３）的结构也有所不同     

C4H5N-(NH3)n氢键团簇的多光子电力与从头计算

在３５５和５３２ｎｍ激光波长下用ＴＯＦ质谱仪研究了Ｃ４Ｈ５Ｎ－（ＮＨ３）ｎ系列氢键团簇体系的多光子电离,实验发现,两波长下除了得到一系列团簇离子Ｃ４Ｈ５Ｎ－（ＮＨ３）ｎ＾＋外,还观测到一系列质子化产物Ｃ４Ｈ５Ｎ－（ＮＨ３）ｎ－Ｈ＾＋,这些质子化产物来自于光电离过程中团簇内部的质子转移反应;Ｃ４Ｈ５Ｎ－（ＮＨ３）ｎ＾＋系列离子出现反常强度变化,即Ｃ４Ｈ５Ｎ－（ＮＨ３）２＾＋离子强度较Ｃ４Ｈ５Ｎ－（Ｎ     

氨和甲醇团簇中的质子转移反应

应用激光多光子电离质谱和分子束技术研究了氨和甲醇二元团簇,实验观测到两个系列质子化的团簇离子: (CH3OH)nH+和(CH3OH)nNH4+(1≤n≤14 ),其产生是经过二元团簇内的质子转移反应。同时也研究了氘代甲醇CH3OD和氨混合团簇,结果表明OD原子团中的D转移概率比CH3原子团中的质子转移概率大几倍。在HF/STO-3G和MP2/6-31G*　*水平上对氨和甲醇二元团簇进行了计算,结果表明与CH3相比OH中的质子转移更加容易,因为CH3中的质子转移过程要克服高度约120 kJ/mol的能垒。     

N_2H_4-CH_3OH氢键团簇体系的从头计算

用从头计算法研究了 (N2 H4-CH3OH)氢键团簇体系。分别在HF/6 31G 和HF/6 31G 水平上对它们的中性和离子团簇进行几何全优化 ,得到了 3种中性混合团簇稳定构型和离子混合团簇稳定构型 ,并对其能量和稳定性进行了比较。讨论了 3种不同构型离子团簇可能的解离通道。给出了质子化混合团簇的稳定构型 ,并对其可能的解离通道进行了讨论。文中最后计算出N2 H4,CH3OH ,(N2 H4-CH3OH)团簇的质子亲和能 (PA) ,分别为 :2 0 6.7kcal/mol,1 78.3kcal/mol,2 2 7.5kcal/mol,其中质子亲和能PAcalc[N2 H4]与实验值PAexp[N2 H4]=2 0 4 .8kcal/mol符合得很好。     

密度泛函理论研究银上吸附对巯基吡啶的SERS化学增强效应

基于密度泛函理论计算和拉曼光谱理论分析,我们研究了对巯基吡啶(4MPY)分子的拉曼光谱和其在银上的表面增强拉曼光谱(SERS),并进一步探讨了SERS与界面吸附结构、异构化、质子化和氢键作用以及低能激发态的关系。首先,我们对两种分子异构体的相对稳定性和拉曼光谱进行了理论分析。在此基础上,进而研究了该分子与不同银簇作用时的拉曼光谱,结果表明,4MPY以巯基硫与银簇作用形成强的Ag―S键,导致拉曼光谱的线型不依赖于所选银簇的大小。接着我们考虑了吡啶氮端作用的两种情况。(1)当4MPY-银簇复合物同时以吡啶氮与水簇或水合质子簇形成氢键时,结果表明吡啶环的部分振动频率随氢键和质子化发生蓝移。(2)当考虑吡啶氮与银簇作用时,吡啶环三角畸变振动发生蓝移。上述情况不仅解释了实验观测的振动频率变化,而且表明了化学环境改变对相对拉曼强度的影响。最后,我们计算了当对巯基吡啶分子以单端或双端与银簇作用,在考虑激发光与低能激发态的能量匹配时,拉曼光谱强度与低能激发态的关系。计算结果表明,在双端吸附构型下,与吡啶氮成键的银簇受激发产生电荷转移态,不仅导致吡啶环v_(12)、v_1和v_(8a)振动的拉曼信号增强,而且选择性地增强吡啶环C―H面内对称弯曲振动v9a的拉曼信号。     

小分子团簇的同步辐射光电离

同步辐射光电离质谱技术是研究小分子团簇的重要手段。通过测量团簇离子的产生阈值,可获得团簇的电离势、离解能、质子亲和能、溶剂化作用能、生成热等热化学数据;通过电离离解产物的测量,可以了解团簇内的质子转移、电子转移、离子-分子反应等弛豫过程。本文对同步辐射光电离质谱实验装置、小分子团簇的热化学及弛豫过程作了较详细的介绍。     

Single photon ionization of van der Waals clusters with a soft x-ray laser: (CO2)n and (CO2)n(H2O)m

Pure neutral (CO2)n clusters and mixed (CO2)n(H2O)m clusters are investigated employing time of flight mass spectroscopy and single photon ionization at 26.5 eV. The distribution of pure (CO2)n clusters decreases roughly exponentially with increasing cluster size. During the ionization process, neutral clusters suffer little fragmentation because almost all excess cluster energy above the vertical ionization energy is taken away by the photoelectron and only a small part of the photon energy is deposited into the (CO2)n cluster. Metastable dissociation rate constants of (CO2)n+ are measured in the range of (0.2-1.5) x 10(4) s(-1) for cluster sizes of 5< or =n< or =16. Mixed CO2-H2O clusters are studied under different generation conditions (5% and 20% CO2 partial pressures and high and low expansion pressures). At high CO2 concentration, predominant signals in the mass spectrum are the (CO2)n+ cluster ions. The unprotonated cluster ion series (CO2)nH2O+ and (CO2)n(H2O)2+ are also observed under these conditions. At low CO2 concentration, protonated cluster ions (H2O)nH+ are the dominant signals, and the protonated CO2(H2O)nH+ and unprotonated (H2O)n+ and (CO2)(H2O)n+ cluster ion series are also observed. The mechanisms and dynamics of the formation of these neutral and ionic clusters are discussed.     

Ionization of methane clusters in helium nanodroplets

The electron ionization of helium droplets doped with methane clusters is investigated for the first time using high-resolution mass spectrometry. The dominant ion products ejected into the gas phase are the unprotonated (CH(4))(n)(+) cluster ions along with the protonated ions, CH(5)(+)(CH(4))(n-1). The mass spectra show clear evidence for magic numbers, which are broadly consistent with icosahedral shell closings. However, unusual features were observed, including different magic numbers for CH(5)(+)(CH(4))(n-1) (n=55, 148) when compared to (CH(4))(n)(+) (n=54, 147). Possible interpretations for some of these differences are proposed. Products of the type [C(2)H(x)(CH(4))(n)](+), which result from ion-molecule chemistry, are also observed and these too show clear magic number features. Finally, we report the first observation of (CH(4))(n)(2+) dications from methane clusters. The threshold for dication survival occurs at n≥70 and is in good agreement with a liquid droplet model for fission of multiply charged ions. Furthermore, we present evidence showing that these dications are formed by an unusual two-step mechanism which is initiated by charge transfer to generate a monocation and is then followed by Penning ionization to generate a dication.     

Protonation and Dehydrogenation During the Multiphoton Ionization of the Cluster: C_4H_5N(H_2O)_n

Proton transfer process in hydrogen-bonded clusters has attracted great interest of many chemists in physical chemistry and biochemistry1-5. Pyrrole (C4H5N) is one of the building blocks of some important biomolecules6. And pyrrole is a compound of five-membered hetero-cyclic aromatic ring, in which a lone pair of electrons offered by the N atom and the two double bonds form a delocalized big ( bond. In this paper we report on the observations for the cluster system pyrrole-water by use of a…     

Hydrogen bonds in 1,4-dioxane/ammonia binary clusters

With synchrotron radiation, we have studied the photoionization and dissociation of 1,4-dioxane/ammonia clusters in a supersonic expansion. The observed major product ions are the 1,4-dioxane cation M(+) and protonated cluster ions M(NH(3))(n)H(+) (where M=1,4-dioxane), and the intensities of the unprotonated cluster ions M(NH(3))(n) (+) are much lower. Fully optimized geometries and energies of the neutral cluster M(NH(3))(2) and related cluster ions have been obtained using the ab initio molecular orbital method and density functional theory. The potential energy surface of the excited state of M(NH(3))(2) (+) was also calculated. With these results, the mechanisms of different photoionization-dissociation channels have been suggested. The most probable channel is electron ejection from the highest occupied molecular orbital, followed by the dissociation into M(+) and (NH(3))(2). For another main channel, after removing an electron from the second highest occupied molecular orbital, the intracluster proton transfer process takes place to form the stable unprotonated cluster ion M(NH(3))H(+)-NH(2), which usually leads to the dissociated protonated cluster ion M(NH(3))H(+) and a radical NH(2).     

Single photon ionization of van der Waals clusters with a soft x-ray laser: (SO2)n and (SO2)n(H2O)m

van der Waals cluster (SO2)n is investigated by using single photon ionization of a 26.5 eV soft x-ray laser. During the ionization process, neutral clusters suffer a small fragmentation because almost all energy is taken away by the photoelectron and a small part of the photon energy is deposited into the (SO2)n cluster. The distribution of (SO2)n clusters decreases roughly exponentially with increasing cluster size. The photoionization dissociation fraction of I[(SO2)(n-1)SO+] / I[(SO2)n+] decreases with increasing cluster size due to the formation of cluster. The metastable dissociation rate constants of (SO2)n+ are measured in the range of (0.6-1.5) x 10(4) s(-1) for cluster sizes 5< or =n< or =16. Mixed SO2-H2O clusters are studied at different experimental conditions. At the condition of high SO2 concentration (20% SO2 partial pressure), (SO2)n+ cluster ions dominate the mass spectrum, and the unprotonated mixed cluster ions (SO2)nH2O+ (1< or =n< or =5) are observed. At the condition of low SO2 concentration (5% SO2 partial pressure) (H2O)nH+ cluster ions are the dominant signals, and protonated cluster ions (SO2)(H2O)nH+ are observed. The mixed clusters, containing only one SO2 or H2O molecule, SO2(H2O)nH+ and (SO2)nH2O+ are observed, respectively.     

Formation and reactions of clusters in the gas phase: small peptides and carboxylic acids

The cluster formation of seventeen small dipeptides with different primary structures and vanillic acid was investigated by means of a neutral laser desorption and supersonic beam expansion followed by multi photon ionization time of flight mass spectrometry. The structures of these clusters have been characterized by mass spectrometric methods as well as by DFT calculations. It is shown that the structure of the cluster from a dipeptide and vanillic acid is described by a hydrogen bond between the phenolic group of the vanillic acid and the N-terminal amino function of the dipeptide. The intensity of the cluster ion and the main fragmentation product, the protonated peptide ion, can be linked to the proton affinity of the peptide. Furthermore the fragmentation reactions of the protonated peptide are accompanied by extensive hydrogen rearrangements yielding both a and y fragments. The intensities of these fragments follow the proton affinity of the dipeptide.     

Investigation of dialkyl tartrate molecular recognition in cluster ions by Fourier transform mass spectrometry: a comparison of chirality effects in gas and liquid phases

Electrospray ionization of equimolar solutions of S-dimethyl tartrate and R-d6-dimethyl tartrate in methanol/water/acetic acid/salt solutions was utilized to investigate molecular recognition processes in solution. Pronounced chirality effects previously reported for formation of the protonated dimer by ion molecule reactions in the gas phase are quantitatively reproduced in experiments which sample solution phase protonated dimers. Ab initio quantum calculations demonstrate that hydrogen bonds in the protonated cluster are responsible for molecular recognition and that Li⁺ bound clusters, which do not exhibit chiral recognition, are primarily bound by electrostatic forces. In contrast with gas phase studies of alkali and ammonium ion core dimers of dimethyl tartrate—which show no chirality effects—ions electrosprayed from solutions containing trace amounts of these ions show pronounced chirality. With increasing salt concentration the apparent chirality effect disappears and a statistical distribution identical to that found for the gas phase is obtained. These observations are rationalized by a kinetic model that considers the displacement of protons by alkali ions in the final stages of desolvation of microdroplets formed in the electrospray process.     

Sources of artefacts in the electrospray ionization mass spectra of saturated diacylglycerophosphocholines: From condensed phase hydrolysis reactions through to gas phase intercluster reactions

The mass spectra of diacylglycerophosphocholine phospholipids comprised of saturated fatty acids (1,2-dipentanoyl-sn-glycero-3-phosphocholine (D5PC); 1,2-dihexanoyl-sn-glycero-3-phosphocholine (D6PC), and 1,2-dimyristoyl-sn-glycero-3-phosphocholine (D14PC)) are sensitive to the electrospray ionization (ESI) conditions. When fresh solutions of phospholipid in 10 mM ammonium acetate are subjected to ESI, protonated oligomeric clusters, [DxPCn + H]+ (x = 5, 6, and 14) are observed in the following different types of mass spectrometers: 3D-quadrupole ion trap; linear ion trap, and triple quadrupole. The formation of the protonated cluster ions is not unique to the ion trap instruments, although they tend to be more abundant in these instruments. As the ESI solutions age, new ions are observed, which correspond to acid-catalyzed solution phase deacylation reactions. The collision induced dissociation fragmentation reactions of the oligomer cluster ions exhibit a distinct dependence on the cluster size, with the larger clusters (n > 2) simply fragmenting via the loss of lipid monomers. In contrast, the fragmentation of the dimeric cluster ion is unique, resulting in a number of additional reactions including covalent bond formation via intermolecular cluster SN2 reactions and SN2 transfer of a methyl group. The nature of the charge has a significant role in the formation of products via these intermolecular cluster reactions. Changing the head group to phosphoethanolamine "switches off" the SN2 reactions, while changing the cation from a proton to either a sodium or a potassium ion, diminishes the intermolecular reactions relative to monomer loss. Semi empirical PM3 calculations on [D6PC2 + H]+ suggest that the SN2 reactions are thermodynamically favored over simple monomer loss. These results have important implications in the field of lipidomics.     

Hydrogen bonding interactions of pyridine*+ with water: stepwise solvation of distonic cations

The solvation energies of the pyridine*+ radical cation by 1-4 H2O molecules were determined by equilibrium measurements in a drift cell. The binding energies of the pyridine*+(H2O)n clusters are similar to the binding energies of protonated pyridine-water clusters, (C5H5NH+)(H2O)n, which involve NH+..OH2 bonds and different from those of the solvated benzene radical cation-water clusters, C6H6*+(H2O)n, which involve CHdelta+..OH2 bonds. These relations indicate that the observed pyridine*+ ions have the distonic *C5H4NH+ structures that can form NH+..OH2 bonds. The observed thermochemistry and ab initio calculations show that these bonds are not affected significantly by an unpaired electron at another site of the ion. Similar observations also identify the 2-fluoropyridine*+ distonic ion. The distonic structure is also consistent with the reactivity of pyridine*+ in H atom transfer, intra-cluster proton transfer and deprotonation reactions. The results present the first measured stepwise solvation energies of distonic ions, and demonstrate that cluster thermochemistry can identify distonic structures.