复合物Mg+-S2(CH3)2的光诱导反应

研究了230~440 nm波段复合物Mg+-S2(CH3)2的单光子光诱导反应. 复合物光诱导产物的质谱揭示, 存在着非反应猝灭产物Mg+和反应产物Mg+SCH3. 复合物的光解离光谱由三个对应于离子Mg+(32P←32S)跃迁的宽谱峰构成. 用量化计算中的CIS方法所得的吸收谱理论值与实验值吻合较好.     

CH3F分子间相互作用的ab initio研究

在MP2/6-311+ +G(3d,3p)电子相关校正水平上,对CH₃F二聚体可能存在的几何构型进行全自由度能量梯度优化和频率验证,发现3种势能面上有极小点的构型.进一步在高级电子相关校正的MP4S-DTQ、CCSD(T)/6-311+ +G(3df,3pd)方法水平上,对其中总能量最小的构型进行精确计算,得到二聚体的结合能为-9.707kJ/mol.研究结果支持了由光谱实验结果推测的构型,解释了CH₃F二聚体的谐振频率的多样性.     

CH3F分子间相互作用的ab initio研究

在MP2/6-311++G(3d,3p)电子相关校正水平上, 对CH3F二聚体可能存在的几何构型进行全自由度能量梯度优化和频率验证, 发现3种势能面上有极小点的构型. 进一步在高级电子相关校正的MP4SDTQ、 CCSD(T)/6-311++G(3df,3pd)方法水平上, 对其中总能量最小的构型进行精确计算, 得到二聚体的结合能为-9.707 kJ/mol. 研究结果支持了由光谱实验结果推测的构型, 解释了CH3F二聚体的谐振频率的多样性.      

电子转移反应O2+O2·-→O2·-+O2的从头算研究

利用abinitio方法,在UHF,UMP2及不同基组3-21G,6-31G^*,6-311+G^*和UMP2(full)/6-311+G^*水平上,研究了O~2/O~2^.^-自交换电子转移反应。优化了电子转移前后反应物和产物的结构,研究了体系能量的变化,计算了自交换电子转移反应的内重组能。对UHF方法和UMP2方法的计算结果进行了比较,并与实验结果进行了对照。结果表明UHF方法由于没有考虑组态相互作用,计算结果存在较大偏差,UMP2(full)/6-311+G^*水平上的计算结果与实验值吻合较好。在UMP2(full)/6-311+G^*水平上计算了气相自交换电子转移反应速率常数。在优化了电子转移复合物结构的基础上考虑了溶剂效应的影响,计算了水溶液中的溶剂重组能。研究结果表明O~2/O~2^.^-体系电子转移反应的活化能主要来源于溶剂重组能的贡献。最后计算了该反应在水溶液中的反应速率常数。理论计算结果与实验值吻合得很好。     

C2F51分子C—I键解离的自旋-轨道从头算研究

采用考虑相对论效应的6—311G^＊＊全电子基组与多参考微扰理论,计算了该分子的包含自旋-轨道耦合效应的垂直激发能和基态、激发态C—I键解离势能曲线．理论计算发现,势能曲线3^3A＂与1^1A＂,2^1A＇出现交叉,交叉区域在C—I键长为0．241nm附近;基态1^A＇到激发态3^3A＂（^3Q0）的垂直激发能为4．658eV,与实验值4．662eV非常吻合．讨论了C2F5I分子作为碘激光介质的可行性．     

TinC2n(n=1-6)分子簇的量子化学从头算研究

用量子化学从头计算方法研究了TinC2n(n=1-6)分子簇的几何构型和电子结构。这些TinC2n分子簇以TiC2为结构单元, 通过C-C或Ti-C键进一步连接而逐渐长大。研究结果可以较好地解释实验现象, 并说明Metcars的形成机理。     

CH自由基与O2反应的从头算研究

采用量子化学从头算法（UMP2／6－31G**水平），从理论上研究了CH＋O2反应的两个主要通道.根据计算所得的反应诸途径（连接反应物Cn＋）及两个通道的最终产物）讨论了复杂的反应机理．发现反应过程涉及O2的第一激发态1△g，且沿反应途径有势能面相交，反应途径中包括多个中间体及过渡态．     

CH3NO2+X(X=H,OH, CH3, CH2[^3B1], O[^3P])→CH2NO2+XH吸氢反应过渡态 结 构和反应位垒的DFT计算研究

采用DFT(B3LYP)方法,分别在6-311g(d,p),6-311++g(d,p)和自洽相关基组cc-pVIZ水平上优化了基态硝基甲烷和自由基H,OH,CH3,CH2[^3B1]以及O[^3P]等发生吸氢反应时的过渡态结构,并计算了反应的位垒。研究表明,对同一反应,不同基组下优化得到的过渡态几何结构基本一致;反应位垒数值的大小也基本接近,经校正,硝基甲烷同自由基反应位垒的理论计算值同实验结果基本吻合。     

H+ClF→HCl+F微观分支反应机理的从头算分子轨道法研究

用从头算分子轨道法对反应H+ClF→HCl+F的势能面进行了系统的研究。在势能面上找到了与该反应相应的两个过渡态, 并通过对从这两个过渡态出发的内禀反应坐标的分析, 得出了H与ClF生成HCl的反应途径存在着微观分支的结论。同时又由H以不同角度进攻ClF中Cl原子一端反应势垒的变化情况, 对势能面上出现分支的原因作出了解释。     

(CH3)2S与HOCI分子间的卤键和氢键相互作用

在DFT-B3LYP/6-311++G**水平上分别求得(CH3)2S…ClOH卤键复合物和(CH3)2S…HOCl氢键复合物势能面上的稳定构型.频率分析表明,与单体HOC1相比,在两种复合物中,10C1-11O和12H-11O键伸缩振动频率发生显著的红移.经MP2/6-311++G**水平计算的含基组重叠误差(BSSE)校正的气相中相互作用能分别为-11.69和-24.16 kJ·mol-1.自然键轨道理论(NBO)分析表明,在(CH3)2s…ClOH卤键复合物中,引起10Cl-11O键变长的因素包括两种电荷转移:(i)孤对电子LP(1S)1→σ*(10C1-11O);(ⅱ)孤对电子LP(1s)2→σ*(10Cl-11O),其中孤对电子LP(lS)2→σ*(10Cl-11O)转移占主要作用,总的结果是使σ(10Cl-11O)的自然布居数增加0.14035e,同时11O原子的再杂化使其与10Cl成键时s成分增加,即具有与电荷转移作用同样的"拉长效应";在(CH3)2s…HOCl氢键复合物中也存在类似的电荷转移,但是11O原子的再杂化不同于前者.自然键共振理论(NRT)进行键序分析表明,在卤键复合物和氢键复合物中,10Cl-11O和12H-11O键的键序都减小.通过分子中原子理论(AIM)分析了复合物中卤键和氢键的电子密度拓扑性质.     

Ab initio study of the F + CH3NHNH2 reaction mechanism

The F + CH(3)NHNH(2) reaction mechanism is studied based on ab initio quantum chemistry methods as follows: the minimum energy paths (MEPs) are computed at the UMP2/6-311++G(d,p) level; the geometries, harmonic vibrational frequencies, and energies of all stationary points are predicted at the same level of theory; further, the energies of stationary points and the points along the MEPs are refined by UCCSD(T)/6-311++g(3df,2p). The ab initio study shows that, when the F atom approaches CH(3)NHNH(2), the heavy atoms, namely N and C atoms, are the favorable combining points. For the two N atoms, two prereaction complexes with C(s) symmetry are generated and there exists seven possible subsequent reaction routes, of which routes 1, 2, 5, and 7 are the main channels. Routes 1, 2, and 5 are associated with HF elimination, with H from the amino group or imido group, and route 7 involves the N-N bond break. Routes 3 and 6 with relation to HF elimination with H from methyl, and route 4 involved the C-N bond break, are all energetically disfavored. For the C atom, the attack of F results in the break of the C-N bond and the products are CH(3)F + NHNH(2). This route is very competitive.     

Theoretical Study of CH3CH=CH2+O(1D) Reaction: Mechanism and Kinetics

The mechanism and kinetics for the reaction of propene(CH₃CH=CH₂) molecule with O(¹D) atom were investigated theoretically. The electronic structure information of the potential energy surface(PES) was obtained at the B3LYP/6-311+G(d,p) level, and the single-point energies were refined by the multi-level MCG3-MPWB method. The calculated results show that O(¹D) atom can attack CH₃CH=CH₂ via the barrierless insertion mechanism to form four energy-riched intermediates CH₃C(OH)CH₂(IM1), CH₃CHCHOH(IM2), CH₂OHCHCH₂(IM3) and cyclo- CH₂OCHCH₃(IM4), respectively, on the singlet PES. The branching ratios as well as the pressure- and temperaturedependence of various product channels for this multi-well reaction were predicted by variational transition-state and Rice-Ramsperger-Kassel-Marcus(RRKM) theories. The present results will be useful to gain a deep insight into the reaction mechanism and kinetics of CH₃CH=CH₂+O(¹D) reaction.     

从头算分子动力学研究O-与CH_3F反应的产物通道

在B3LYP/6-31+G(d,p)理论水平下采用基于波恩-奥本海默近似的从头算分子动力学方法重新研究了O-与CH3F反应经抽氢生成OH-和生成H2O的两条产物通道.反应轨线从反应初始过渡态开始,采用300K时的热取样确定初始条件,同时为对比不同的初始碰撞平动能条件下产物通道的变化,分别限定过渡矢量上的能量为2.1、36.8及62.8kJ·mol-1进行轨线计算,所有轨线计算的结果表明抽氢生成OH-的过程始终为主要的产物通道.我们的计算不仅进一步证实了以往实验的结论,而且描绘了抽氢生成OH-和生成H2O这两个产物通道在反应出口势能面上的动态反应路径,更为深刻地揭示了该反应的微观机理.     

Ab initio and direct quasiclassical-trajectory study of the F+CH4-->HF+CH3 reaction

We present an electronic structure and dynamics study of the F+CH4-->HF+CH3 reaction. CCSD(T)/aug-cc-pVDZ geometry optimizations, harmonic-frequency, and energy calculations indicate that the potential-energy surface is remarkably isotropic near the transition state. In addition, while the saddle-point F-H-C angle is 180 degrees using MP2 methods, CCSD(T) geometry optimizations predict a bent transition state, with a 153 degrees F-H-C angle. We use these high-quality ab initio data to reparametrize the parameter-model 3 (PM3) semiempirical Hamiltonian so that calculations with the improved Hamiltonian and employing restricted open-shell wave functions agree with the higher accuracy data. Using this specific-reaction-parameter PM3 semiempirical Hamiltonian (SRP-PM3), we investigate the reaction dynamics by propagating quasiclassical trajectories. The results of our calculations using the SRP-PM3 Hamiltonian are compared with experiments and with the estimates of two recently reported potential-energy surfaces. The trajectory calculations using the SRP-PM3 Hamiltonian reproduce quantitatively the measured HF vibrational distributions. The calculations also agree with the experimental HF rotational distributions and capture the essential features of the excitation function. The results of the SRP semiempirical Hamiltonian developed here clearly improve over those using the two prior potential-energy surfaces and suggest that reparametrization of semiempirical Hamiltonians is a promising strategy to develop accurate potential-energy surfaces for reaction dynamics studies of polyatomic systems.     

Isomerization of CH3O+=CHCH3 to CH2=O+CH2CH3

Ab initio calculations establish that CH₃O⁺=CHCH₃ (1) rearranges in gas phase isolation to CH₂=O⁺C₂H₅ (2) directly rather than through CH₃OCH₂CH ₂ ⁺ (3). The reaction is predicted to be antarafacial, in accord with the Woodward-Hoffmann (W-H) predictions. We predict an activation energy of 212.0 kJ/mol for this process at the QCISD(T)/6-311G**//MP2/6-311G** level. We also reinvestigated the degenerate rearrangement of CH₃O=CH ₂ ⁺ by a 1,3-sigmatropic shift. The W-H model is not a good one for the transition state (TS) for the latter reaction because the π bonding has been completely broken off. That TS is stabilized by three-center bonding between the carbons and the hydrogen being transferred. We also examined the questions of the importance of polarization functions on hydrogen and a set of outer valence functions on all the atoms in describing these hydrogen transfer TSs, and whether it is necessary to include these functions in the TS optimization runs. For the rearrangements we studied, polarization functions on hydrogen are crucial only for 1,2 hydrogen shifts. The 6-31G* basis set is adequate and good for the optimization of TSs of other ring sizes. For the 1,3 and 1,4 shifts we examined, a combination of both outer valence functions and polarization functions on hydrogen causes reductions in the computed activation energies ranging from 5.9 kJ/mol for the 1,4 shift at the RHF level to 15.6 kJ/mol for the 1,3 shift at the MP2 level.     

CH2F自由基与HNCO反应机理的理论研究

The reaction mechanism of CH2F radical with HNCO was investigated by density functional theory (DFT)at the B3LYP/6-311++G(d,p) level. The geometries of the reactants, the intermediates, the transition states and the products were optimized. The transition states were verified through the vibration analysis.The relative energies were calculated at the QCISD(T)/6-311++G**//B3LYP/6-311++G(d,p) level. Seven feasible reaction pathways of the reaction were studied. The results indicate that the pathway (5) is the most favorable to occur, so it is the main pathway of the reaction.     

F+CH2CO的反应机理和动力学研究

用G3(MP2)方法对F与CH₂CO的反应进行研究,揭示了该反应的加成-消除机理.F原子首先与CH₂CO作用形成富能的中间体CH₂FCO^*,此加成反应为无势垒过程.富能的CH₂FCO^*可进一步发生解离或异构化反应生成各种可能的产物.其中CO和CH₂F可能为反应的主要产物.根据从头算的结果,用RRKM-TST理论计算该反应的速率常数.总包反应速率常数与温度存在弱的依赖关系,与总压力无关.