Indene Formation under Single‐Collision Conditions from the Reaction of Phenyl Radicals with Allene and Methylacetylene—A Crossed Molecular Beam and Ab Initio Study

Polycyclic aromatic hydrocarbons (PAHs) are regarded as key intermediates in the molecular growth process that forms soot from incomplete fossil fuel combustion. Although heavily researched, the reaction mechanisms for PAH formation have only been investigated through bulk experiments; therefore, current models remain conjectural. We report the first observation of a directed synthesis of a PAH under single‐collision conditions. By using a crossed‐molecular‐beam apparatus, phenyl radicals react with C₃H₄ isomers, methylacetylene and allene, to form indene at collision energies of 45 kJ mol^?1. The reaction dynamics supported by theoretical calculations show that both isomers decay through the same collision complex, are indirect, have long lifetimes, and form indene in high yields. Through the use of deuterium‐substituted reactants, we were able to identify the reaction pathway to indene.     

The Effect of Boron on the Properties of Glucomannan： An Experimental and Molecular Dynamics Simulation Study

1 INTRODUCTION gel using KGM and borax at 60 ℃, which can be used as slow-released reagent of theophylline and Generally, the mixture of Konjac Glucomanan dibucaine. And Hogi Tsuneo utilized KGM and tetra- (KGM) and salts that could be hydrolyzed to form valent boric acid to prepare artificial crystal[1]. This multi-hydroxyl hydrates leads to the generation of kind of crystal has good light transmission property, gelatum. Among the familiar salts, such as borate, elasticity, intensi…     

Analysis of Nascent Rotational Energy Distributions and Reaction Mechanisms of the Gas‐Phase Radical–Radical Reaction O(3P)+(CH3)2CH→C3H6+OH

This paper reports on the gas‐phase radical–radical dynamics of the reaction of ground‐state atomic oxygen [O(³P), from the photodissociation of NO₂] with secondary isopropyl radicals [(CH₃)₂CH, from the supersonic flash pyrolysis of isopropyl bromide]. The major reaction channel, O(³P)+(CH₃)₂CH→C₃H₆ (propene)+OH, is examined by high‐resolution laser‐induced fluorescence spectroscopy in crossed‐beam configuration. Population analysis shows bimodal nascent rotational distributions of OH (X²Π) products with low‐ and high‐N′′ components in a ratio of 1.25:1. No significant spin–orbit or Λ‐doublet propensities are exhibited in the ground vibrational state. Ab initio computations at the CBS‐QB3 theory level and comparison with prior theory show that the statistical method is not suitable for describing the main reaction channel at the molecular level. Two competing mechanisms are predicted to exist on the lowest doublet potential‐energy surface: direct abstraction, giving the dominant low‐N′′ components, and formation of short‐lived addition complexes that result in hot rotational distributions, giving the high‐N′′ components. The observed competing mechanisms contrast with previous bulk kinetic experiments conducted in a fast‐flow system with photoionization mass spectrometry, which suggested a single abstraction pathway. In addition, comparison of the reactions of O(³P) with primary and tertiary hydrocarbon radicals allows molecular‐level discussion of the reactivity and mechanism of the title reaction.     

Dendrimer Disassembly in the Gas Phase: A Cascade Fragmentation Reaction of Fréchet Dendrons

The mass spectrometric characterization of Fréchet‐type dendrons is reported. In order to provide the charges necessary for electrospray ionization, dendrons bearing an OH group at the focal point can be deprotonated and observed in the negative ion mode. Alternatively, the corresponding bromides can be converted to quaternary ammonium ions that can easily be detected in the positive mode. If the latter ions are subjected to collision‐induced dissociation experiments, a fragmentation cascade begins with the dissociation of the focal amine. The focal benzyl cation quickly decomposes in a fragmentation cascade from the focal point to the periphery until the peripheral benzyl (or naphthylmethyl) cations are formed. Five different mechanisms are discussed in detail, three of which can be excluded based on experimental evidence. The cascade fragmentation is reminiscent of self‐immolative dendrimers.     

分子束中生物分子的光谱与结构

研究分子束中的生物分子有助于探讨生物分子的固有性质和由于生物环境而引起的其他性质之间的区别。本文首先介绍了一种可将生物分子在气相中"孤立"的实验技术,即激光解吸并分子束冷却技术,同时还介绍了与该研究方向相关的光谱方法,即UV/UV和IR/UV烧孔光谱等。并回顾了近年来人们应用这些实验技术对分子束中的氨基酸和短肽、核酸碱基、糖类和神经递质类分子以及它们的团簇最新研究进展。文中还简要介绍了一种新的应用于构象异构动力学研究的光谱方法,即激励辐射泵浦-注孔(SEP-HF)和激励辐射泵浦-布居转移(SEP-PT)。最后,综述了短肽离子光解离动力学和短肽离子中发生的电荷快速转移动力学过程的研究进展。     

Solid-solid phase transitions: interface controlled reactivity and formation of intermediate structures

Finding new pathways to novel materials is an open challenge in modern solid-state chemistry. Among the reasons that still prevent a rational planning of synthetic routes is the lack of an atomistic understanding at the moment of phase formation. Metastable phases are, in this respect, powerful points of access to new materials. For the synthetic efforts to fully take advantage of such peculiar intermediates, a precise atomistic understanding of critical processes in the solid state in its many facets, that is, nucleation patterns, formation and propagation of interfaces, intermediate structures, and phase growth, is mandatory. Recently we have started a systematic theoretical study of phase transitions, especially of processes with first-order thermodynamics, to reach a firm understanding of the atomistic mechanisms governing polymorphism in the solid state. A clear picture is emerging of the interplay between nucleation patterns, the evolution of domain interfaces and final material morphology. Therein intermediate metastable structural motifs with distinct atomic patterns are identified, which become exciting targets for chemical synthesis. Accordingly, a new way of implementing simulation strategies as a powerful support to the chemical intuition is emerging. Simulations of real materials under conditions corresponding to the experiments are shedding light onto yet elusive aspects of solid-solid transformations. Particularly, sharp insights into local nucleation and growth events allow the formulation of new concepts for rationalizing interfaces formed during phase nucleation and growth. Structurally different and confined in space, metastable interfaces occurring during polymorph transformations bring about distinct diffusion behavior of the chemical species involved. More generally, stable structures emerge as a result of the concurrence of the transformation mechanism and of chemical reactions within the phase-growth fronts.     

Mechanisms for the Breakdown of Halomethanes through Reactions with Ground‐State Cyano Radicals

One route to break down halomethanes is through reactions with radical species. The capability of the artificial force‐induced reaction algorithm to efficiently explore a large number of radical reaction pathways has been illustrated for reactions between haloalkanes (CX₃Y; X=H, F; Y=Cl, Br) and ground‐state (²Σ⁺) cyano radicals (CN). For CH₃Cl+CN, 71 stationary points in eight different pathways have been located and, in agreement with experiment, the highest rate constant (10⁸ s^?1 M ^?1 at 298 K) is obtained for hydrogen abstraction. For CH₃Br, the rate constants for hydrogen and halogen abstraction are similar (10⁹ s^?1 M ^?1), whereas replacing hydrogen with fluorine eliminates the hydrogen‐abstraction route and decreases the rate constants for halogen abstraction by 2–3 orders of magnitude. The detailed mapping of stationary points allows accurate calculations of product distributions, and the encouraging rate constants should motivate future studies with other radicals.     

三氟化硼和水反应的密度泛函理论研究

应用密度泛函理论对三氟化硼和水的反应进行了研究. 在 B3PW91/6-31＋＋G(d,p)水平上优化了各驻点(反应物, 中间体, 过渡态和产物)的几何构型, 并计算了它们的振动频率和零点振动能, 并对能量进行了校正. 计算结果表明, 三氟化硼和水的反应比较复杂, 产物除氟化氢外, 还有硼酸, 氟硼酸, 硼氟氧酸等.     

The gas phase aldose‐ketone isomerization mechanism: Direct interconversion of the model hydroxycarbonyls 2‐hydroxypropanal and hydroxyacetone

We report a novel mechanism for the interconversion of 2‐hydroxypropanal with its more‐stable ketone isomer hydroxyacetone. Reaction proceeds via concerted transfer of two H atoms, requires a barrier of only ～40 kcal mol^?1, bypasses the enediol intermediate, and is general for α‐hydroxy carbonyls. A similar isomerization mechanism is shown to persist for β, γ, and δ‐hydroxy carbonyls; these compounds are skeletal forms of the monosaccharides and this work, therefore, discloses the gas‐phase mechanism for aldose‐ketose isomerization. As an example, the isomerization of glyceraldehyde to dihydroxyacetone is shown to proceed via this mechanism with a barrier of 31 kcal mol^?1. Rate coefficients and thermochemical properties are reported for the isomerization of 2‐hydroxypropanal and hydroxyacetone for use in detailed kinetic models. Additionally, RRKM theory k (E ) values for this reaction suggest that it may transpire in the troposphere following solar excitation.     

Gas‐Phase Reaction of CeV2O7+ with C2H4: Activation of CC and CH Bonds

The reactivity of metal oxide clusters toward hydrocarbon molecules can be changed, tuned, or controlled by doping. Cerium‐doped vanadium cluster cations CeV₂O₇⁺ are generated by laser ablation, mass‐selected by a quadrupole mass filter, and then reacted with C₂H₄ in a linear ion trap reactor. The reaction is characterized by a reflectron time‐of‐flight mass spectrometer. Three types of reaction channels are observed: 1) single oxygen‐atom transfer , 2) double oxygen‐atom transfer , and 3) C?C bond cleavage. This study provides the first bimetallic oxide cluster ion, CeV₂O₇⁺, which gives rise to C?C bond cleavage of ethene. Neither Ce_xO_y^± nor V_xO_y^± alone possess the necessary topological and electronic properties to bring about such a reaction.     

Theoretical and Experimental Study of Complex Ions from Reactions of Al+ (Cu+) with Amine Molecules

The gas phase reactions of metal ions (Al⁺, Cu⁺) with amine molecules [CH₃NH₂=MA, (CH₃)₂NH=DMA] were investigated using a laser ablation‐molecular beam method. The directly associated product complex ions,Al⁺‐MA and Al⁺‐DMA, and the dehydrogenation product ions, Cu⁺(CH₂NH) and Cu⁺(C₂H₅N), as well as hydrated ion Cu⁺(NC₂H₅·H₂O), have been obtained and recorded from the reactions of the metal ions and organic amine molecules, and density functional theory (B3LYP) calculations have been performed to reveal the optimized geometry, energetics, and reaction mechanism of the title reactions with basis set 6‐311+G(d,p) adopted.     

Nef Reaction with Molecular Oxygen in the Absence of Metal Additives,and Mechanistic Insights

A Nef reaction has been developed that is conducted under mildly basic conditions with molecular oxygen as an oxidant, without the need for metal additives. Whereas nitroalkanes are converted into ketones in good yield, nitroalkenes are transformed into α,β‐unsaturated ketones in one‐pot by double‐bond isomerization followed by the oxygen‐mediated Nef reaction. The reaction protocol is both mild and general, and tolerates acid‐ and base‐labile functionality or protecting groups. When oxygen‐saturated solvents are employed, the reaction completes within 20 min. Mechanistically, the addition of nitronate ion and molecular oxygen is proposed to proceed initially through a single‐electron transfer event, as indicated by radical clock experiments. This ultimately generates a putative 1,1‐dioxirane, which reacts further with another nitronate ion to generate the ketone. Involvement of a 1,1‐dioxirane is supported by intramolecular trapping experiments with sulfide at the γ‐position of the nitro‐moiety.     

Photolysis of o‐Nitrobenzaldehyde in the Gas Phase: A New OH. Formation Channel

New route to gas‐phase OH^. : UV photolysis of gaseous o‐nitrobenzaldehyde forms OH radicals via the transformation into the ketene or o‐nitrosobenzoic acid intermediate (see figure). The OH^. product is monitored by single‐photon laser‐induced fluorescence (LIF).

     

Kinetics and Mechanisms for the Reactions of Phenyl Radical with Ketene and its Deuterated Isotopomer: An Experimental and Theoretical Study

Kinetics and mechanism for the reaction of phenyl radical (C₆H₅) with ketene (H₂C_β?C_α?O) were studied by the cavity ring‐down spectrometric (CRDS) technique and hybrid DFT and ab initio molecular orbital calculations. The C₆H₅ transition at 504.8 nm was used to detect the consumption of the phenyl radical in the reaction. The absolute overall rate constants measured, including those for the reaction with CD₂CO, can be expressed by the Arrhenius equation k=(5.9±1.8)×10¹¹ exp[?(1160±100)/T] cm³ mol^?1 s^?1 over a temperature range of 301–474 K. The absence of a kinetic isotope effect suggests that direct hydrogen abstraction forming benzene and ketenyl radical is kinetically less favorable, in good agreement with the results of quantum chemical calculations at the G2MS//B3LYP6‐31G(d) level of theory for all accessible product channels, including the above abstraction and additions to the C_α, C_β, and O sites. For application to combustion, the rate constants were extrapolated over the temperature range of 298–2500 K under atmospheric pressure by using the predicted transition‐state parameters and the adjusted entrance reaction barriers E_α=E_β=1.2 kcal mol^?1; they can be represented by the following expression in units of cm³ mol^?1 s^?1: k_α=6.2×10¹⁹ T^?2.3 exp[?7590/T] and k_β=3.2×10⁴ T^2.4 exp[?246/T].