热氢原子碰撞导致的CO2(v3)的高振动激发

用时间分辨-傅里叶变换红外发射光谱研究了热的氢原子与CO2分子间高效率的平动-振动(T-V)能传递.热的氢原子由ArF激光光解H2S得到,这种氢原子的平动能为223 kJ/mol.实验中观察到了从2130 cm-1到2400 cm-1的红外发射谱带,它归属于高振动激发的CO2分子的非对称伸缩振动(v3).对这一发射谱带的光谱拟合显示CO2的非对称伸缩振动被激发到了较高的振动态,振动量子数达到了v=7.并且有5580 cm-1的能量经传能过程由氢原子到达了CO2的v3模.实验条件下氢原子与CO2的T-V传能效率为0.30.实验结果与Schatz等人的用3D半经典计算预测的碰撞截面符合的很好.     

CH_2(~3B_1)自由基与O_2的反应

用时间分辨宫里叶红外发射谱仪（TR-FTIRS），研究了自由基与O2反应的通道及产物的振动态布居．基电子态自由基由351nm紫外激光光解CH2CO生成．观测到振动激发态反应产物CO（v　10）、CO2（v3　7）、OH（H2O）和H2CO的红外发射，证实存在生成H2CO的通道．由光谱拟合得到不同时刻CO（v）和CO2（v2）的相对振动布居，发现v＝4能级的布居数相对于v3　3能级有明显反转．     

O(~1D)+Si(CH_3)_3Cl反应生成振动激发的OH(υ≤5)

实验光谱学和理论计算都发现,“重原子”能隔离分子中的某些振动能景,如SiH_4中Si—H振动泛频的“局域模”.Roger 等在研究F 原子与M(CH_2CH=CH_2)_4(M=Sn,Ge)的反应中,发现了Sn,Ge 对过剩能量转移到其它部分有强烈的阻碍作用(在中间态的寿命时间内).最近,在研究O(~1D)+M(CH_3)_4生成OH(v)反应中,观测到类似的现象.M=C 时,Lutz 用激光诱导荧光方法检测OH 的振动分布,振动是冷的,v=1与v=0的布居比为0.05,     

H+O_2体系在低碰撞能下的动力学研究

本文用准经典轨迹理论,模拟了H(~2S)原子与O_2(~3Σ_g~-)分子在ab initio势能面上的反应碰撞过程,研究了该反应体系在低碰撞能E=0.3eV,O_2的量子态v(振动量子数)=2,j(转动量子数)=1,20,40,60,80,100时的动力学行为。计算结果表明:(1)发生反应的最大碰撞参数b_(max)为4.5a_o,(2)产生最大反应几率的碰撞参数b随j的增加而减小,(3)反应截面随j单调增加,(4)对于小b高j时的非弹性碰撞,产物O_2的振动量子数v′和转动量子数j′均明显地下降,而对于反应碰撞,产物OH(~2Π)多处于基振动态(v′=0),且随j的增加,产物OH处于振动激发态(v′>0)的几率明显增加,当j=100时,甚至出现振动态分布倒反现象。此外,还绘制了部分典型的碰撞轨迹图。     

12CO(A1Π)与13CO(X1∑+)电子传能得多光子电离光谱研究

用双色共振多光子电离光谱(REMPI)方法, 在77 K温度下对~(12)CO(A~1H)与~(13)CO(X~1∑~+)之间的碰撞传能过程进行了研究. 发现二者之间的电子能量转移极快, 并测量了其不同振动通道的速率, 得到~(12)CO(A~1П)V=1、2、3与~(13)CO(X~1∑~+)V=0之间的电子传能总截面分别为1.14±0.42、0.22±0.04、0.17±0.06 nm, 还测量了产物的∧分裂П~+和П~-的布局比, 发现П~+布居总是多于П~-. 从激基复合物生成的观点对传能机理和∧双重态布居的倾向性进行了讨论。     

CO(υ)高振动激发态向C_2H_2的振动传能研究

用时间分辨窝里叶红外发射谱研究了高振动激发态CO向C2H2的传能，得到了CO（v＝1－3）各振动态布展及其随时间的变化,利用微分法解出弛豫微分方程组，获得CO（v=1-3）向C2H2的传能速率常数分别为：2．0±0．1，6.0±0．2和9．1±0.8（10-13cm3·molecule-1·s-1）．传能速率随着振动量子数的增加而迅速增加．CO的振动能应向C2H2的对称伸缩模v2近共振V－V传递．传能过程中还可能形成二聚体络合物，加速了CO（v）向C2H2的传能．用abinitio方法确定了CO...C2H2两种可能的直线构型．     

D CH_4反应的SVRT含时波包理论研究

基于Jordan和Gilbert势能面,用SVRT(semirigidvibratingrotortarget)模型,对D CH4反应进行了含时波包动力学研究,计算得到了不同初始振动转动态的总反应几率、积分散射截面和热速率常数.计算结果与H CH4反应进行了比较和讨论.反应几率随平动能的变化曲线呈现出显著的量子共振特性.通过对j=0时,v=0、1、2的反应几率的计算,看出H-CH3的振动激发极大地提高了反应几率,而反应阈能明显降低,说明反应分子的振动能对分子的碰撞反应有重要贡献.对v=0时,j=0、1、2、3的反应几率的计算,得出转动量子数j的增大也会使反应几率有较大的提高,但反应阈能基本不变.     

D＋CH4反应的SVRT含时波包理论研究

基于Jordan和Gilbert势能面,用SVRT(semirigid vibrating rotor target)模型,对D＋CH4反应进行了含时波包动力学研究,计算得到了不同初始振动转动态的总反应几率、积分散射截面和热速率常数.计算结果与H＋CH4反应进行了比较和讨论.反应几率随平动能的变化曲线呈现出显著的量子共振特性.通过对j=0时,v=0、1、2的反应几率的计算,看出H－CH3的振动激发极大地提高了反应几率,而反应阈能明显降低,说明反应分子的振动能对分子的碰撞反应有重要贡献.对v=0时,j=0、1、2、3的反应几率的计算,得出转动量子数j的增大也会使反应几率有较大的提高,但反应阈能基本不变.     

氢原子共线交换反应的动力学计算 Ⅱ.在反应势能面上Cl+HCl(v)碰撞对的振动去激

本文用一维量子散射方法,计算了氢原子交换反应Cl+HCl(v≤3)→ClH(v′≤3)+Cl。得到了各振动态间反应和非反应非弹性几率。结果表明反应和非反应非弹性几率均呈振荡变化。反应与非反应去激几率相差不大,预期在Cl原子与HCl(v=1,2,3)碰撞去激过程中,反应和非反应散射都是一种有效的机理;此与Wilkins的轨迹结果相符。去激几率与始终态振动量子数密切相关,我们归纳出公式:P_(vv′)≈10~(v+v′-2(v″+1))P_(vv″),(v>v′>v″)。与Moor的实验结果符合较好。     

金催化CO氧化湿度增强效应的理论研究

实验发现纳米金催化的CO氧化有良好的湿度增强效应,但有关机制仍不清楚.我们应用密度泛函理论研究了湿度增强效应的微观机制,以Au4团簇为例,研究了金催化CO氧化的微观机理,考察了H2O在反应中的角色和作用.计算结果表明,H2O与Au4团簇一样,在反应中扮演催化剂的角色,参与反应的进行、改变反应历程、降低反应能垒.催化循环包含4个基元步骤：O2＋H2O→OOH＋OH,CO＋OOH→CO2＋OH,CO＋OH→COOH,和COOH＋OH→CO2＋H2O,其中自由基OOH和OH的形成是催化循环的速控步骤,其能垒为100.31kJ/mol,明显低于非水参与反应的能垒（161.41kJ/mol）.目前的结果合理地解释了实验观测的CO催化氧化的湿度增强效应,给出了其微观反应机制.     

H原子与CO2分子碰撞的化学反应与能量转移

Collisions between hot H atoms and CO2 molecules were studied experimentally by time-resolved Fourier transform infrared emission spectroscopy. H atoms with three translational energies, 174.7, 241.0 and 306.2 kJ/mol respectively, were generated by UV laser photolysis to initiate a chemical reaction of H+CO2!OH+CO. Vibrationally excited CO (v≤2) was observed in the spectrum, where CO was the product of the reaction. The highly efficient T-V energy transfer from the hot H atoms to the CO2 was verified too. The highest vibrational level of v=4 in CO2 (v≤3) was found. Rate ratio of the chemical reaction to the energy transfer was estimated as 10.     

Quantum and classical studies of the O(3P) + H2(v = 0-3,j = 0) --> OH + H reaction using benchmark potential surfaces

We present results of time-dependent quantum mechanics (TDQM) and quasiclassical trajectory (QCT) studies of the excitation function for O(3P) + H2(v = 0-3,j = 0) --> OH + H from threshold to 30 kcal/mol collision energy using benchmark potential energy surfaces [Rogers et al., J. Phys. Chem. A 104, 2308 (2000)]. For H2(v = 0) there is excellent agreement between quantum and classical results. The TDQM results show that the reactive threshold drops from 10 kcal/mol for v = 0 to 6 for v = 1, 5 for v = 2 and 4 for v = 3, suggesting a much slower increase in rate constant with vibrational excitation above v = 1 than below. For H2(v > 0), the classical results are larger than the quantum results by a factor approximately 2 near threshold, but the agreement monotonically improves until they are within approximately 10% near 30 kcal/mol collision energy. We believe these differences arise from stronger vibrational adiabaticity in the quantum dynamics, an effect examined before for this system at lower energies. We have also computed QCT OH(v',j') state-resolved cross sections and angular distributions. The QCT state-resolved OH(v') cross sections peak at the same vibrational quantum number as the H2 reagent. The OH rotational distributions are also quite hot and tend to cluster around high rotational quantum numbers. However, the dynamics seem to dictate a cutoff in the energy going into OH rotation indicating an angular momentum constraint. The state-resolved OH distributions were fit to probability functions based on conventional information theory extended to include an energy gap law for product vibrations.     

Photodissociation dynamics of phenol

The photodissociation of phenol at 193 and 248 nm was studied using multimass ion-imaging techniques and step-scan time-resolved Fourier-transform spectroscopy. The major dissociation channels at 193 nm include cleavage of the OH bond, elimination of CO, and elimination of H(2)O. Only the former two channels are observed at 248 nm. The translational energy distribution shows that H-atom elimination occurs in both the electronically excited and ground states, but elimination of CO or H(2)O occurs in the electronic ground state. Rotationally resolved emission spectra of CO (1 相似文献   

CH2(X 3B1)自由基与O2的反应

用时间分辨富里叶红外发射谱仪（ＴＲ－ＦＴＩＲＳ）研究了ＣＨ２（Ｘ＾３Ｂ１）自由基与Ｏ２反应的通道及产物的振动动态布居，基电子态自由基ＣＨ２（Ｘ＾３Ｂ１）由３５１ｎｍ紫外激光光解ＣＨ２ＣＯ生成，观测到振动发态反应产物ＣＯ（ｖ≤１０），ＣＯ２（ｖ３≤７）ＯＨ（Ｈ２Ｏ）和Ｈ２ＣＯ的红外发射，证实存在生成Ｈ２ＣＯ的通道，由光谱拟合得到不同时刻ＣＯ（ｖ）和ＣＯ２（ｖ３）的相对振动布居，发现ｖ＝４能级的布居数     

Reaction Channels of HCO with NO Study by Time-resolved TR-FTIR Spectroscope

The gaseous reaction of CH+NO2 has been investigated experimentally. CH radical was generated by multiple photon photolysis of CHBr3 at 248 nm. Vibrationally excited species of HCO (ν3), CO(v), CO2(ν3), HNO (ν1), OH(v) were detected as emitters of CH+NO2 reaction by time-resolved Fourier transform spectroscope. Three exothermic reaction channels leading to HCO+NO, NH+CO2, CO+HNO, are identified. The minor reaction leading to OH+NCO may also occur.     

The reaction products of the 193 nm photolysis of vinyl bromide and vinyl chloride studied by time-resolved Fourier transform infrared emission spectroscopy

Time-resolved Fourier transform infrared (TRFTIR) emission spectroscopy has been used to study the 193 nm photolysis of vinyl bromide (C(2)H(3)Br) and vinyl chloride (C(2)H(3)Cl). Time-resolved IR emission was analysed to obtain nascent vibrational state populations of two primary photolysis products: HBr (v = 1-7) and HCl (v = 1-6). In both cases the nascent vibrational state populations monotonically decrease with increasing v and are in excellent agreement with previously published data. Time-resolved populations were analysed to yield rate constants for vibrational relaxation of HBr (v = 1-3) and HCl (v = 1-4) by parent vinyl bromide and vinyl chloride, respectively. In both cases the rate constants were found to increase with increasing vibrational quantum number, in agreement with a single quantum de-excitation via vibrational to vibrational energy transfer. Butadiene (C(4)H(6)) was identified as a secondary product of the photolysis of both vinyl halides, and shown to be formed from the reaction of parent vinyl halide with the vinyl radical. The presence of a buffer gas was found to produce a strong emission feature centred at 2,200 cm(-1), the intensity of which was dependent on the pressure of the buffer gas used, and whose kinetics are indicative of a secondary reaction product. We propose that this emission is from the vibrational progression of the electronic transition A(0, v, 1) --> X(0, v, 2) in the secondary reaction product C(2)H, whose formation route is favoured by the presence of buffer gas.     

Communication: state-to-state quantum dynamics study of the OH + CO → H + CO2 reaction in full dimensions (J = 0)

A full dimensional state-to-state quantum dynamics study is carried out for the prototypical complex-formation OH + CO → H + CO(2) reaction in the ground rovibrational initial state on the Lakin-Troya-Schatz-Harding potential energy surface by using the reactant-product decoupling method. With three heavy atoms and deep wells on the reaction path, the reaction represents a huge challenge for accurate quantum dynamics study. This state-to-state calculation is the first such a study on a four-atom reaction other than the H(2) + OH ? H(2)O + H and its isotope analogies. The product CO(2) vibrational and rotational state distributions, and product energy partitioning information are presented for ground initial rovibrational state with the total angular momentum J = 0.     

Dissociative chemisorption of H2 on the Cu(110) surface: a quantum and quasiclassical dynamical study

Six-dimensional quantum dynamical and quasiclassical trajectory (QCT) calculations are reported for the reaction and vibrationally inelastic scattering of (v = 0,1,j = 0) H(2) scattering from Cu(110), and for the reaction and rovibrationally elastic and inelastic scattering of (v = 1,j = 1) H(2) scattering from Cu(110). The dynamics results were obtained using a potential energy surface obtained with density functional theory using the PW91 functional. The reaction probabilities computed with quantum dynamics for (v = 0,1,j = 0) were in excellent agreement with the QCT results obtained earlier for these states, thereby validating the QCT approach to sticking of hydrogen on Cu(110). The vibrational de-excitation probability P(v=1,j = 0 --> v = 0) computed with the QCT method is in remarkably good agreement with the quantum dynamical results for normal incidence energies E(n) between 0.2 and 0.6 eV. The QCT result for the vibrational excitation probability P(v = 0,j = 0 --> v = 1) is likewise accurate for E(n) between 0.8 and 1 eV, but the QCT method overestimates vibrational excitation for lower E(n). The QCT method gives probabilities for rovibrationally (in)elastic scattering, P(v = 1,j = 1 --> v('),j(')), which are in remarkably good agreement with quantum dynamical results. The rotationally averaged, initial vibrational state-selective reaction probability obtained with QCT agrees well with the initial vibrational state-selective reaction probability extracted from molecular beam experiments for v = 1, for the range of collision energies for which the v=1 contribution to the measured total sticking probability dominates. The quantum dynamical probabilities for rovibrationally elastic scattering of (v = 1,j = 1) H(2) from Cu(110) are in good agreement with experiment for E(n) between 0.08 and 0.25 eV.     

Time-dependent wave packet quantum and quasi-classical trajectory study of He + H₂⁺, D₂⁺ → HeH⁺ + H, HeD⁺ + D reaction on an accurate FCI potential energy surface

The quantum scattering dynamics and quasi-classical trajectory (QCT) calculations have been carried out for the title reaction on an accurate potential energy surface (PES) computed using the full configuration interaction (FCI). On the basis of the PES, the integral cross-sections of He + H?? (v = 0-3, j = 1) → HeH? + H reaction have been calculated, and the results are generally agreed with the experimental cross-sections obtained by Tang et al. [J. Chem. Phys. 2005, 122, 164301] after taking into account the experimental uncertainties, which proves the reliability of implementing dynamics calculations on the FCI PES. The reaction probability of He + D?? (v = 0-2, j = 0) → HeD? + D reactions for total angular momentum J = 0 and the integral cross-section (ICS) have been calculated. The significant quantum effect has been explored by the comparison between the QCT reaction probabilities (or ICS) and the quantum mechanical (QM) reaction probabilities (or ICS), which may be attributed to the deep well in the PES of this light atoms system. Furthermore, the role of Coriolis coupling (CC) effects has also been found not important by the comparison between the CC calculation and the centrifugal sudden (CS) approximation calculation, except that the CC total cross-sections for the v = 1 and 2 states show the collision energy-dependent behaviors in the low-energy area, which are different from those based on the CS calculation.     

Reaction of CH3 with NO2

The elementary reaction of the CH3 radical with NO2 was investigated by time-resolved FTIR spectroscopy and quantum chemical calculations. The CH3 radical was produced by laser photolysis of CH3Br or CH3I at 248 nm. Vibrationally excited products OH, HNO and CO2 were observed by the time-resolved spectroscopy for the first time. The formation of another product NO was also verified. According to these observations, the product channels leading to CH3O+NO, CH2NO+OH and HNO+H2CO were identified. The channel of CH3O+NO was the major one. The reaction mechanisms of the above channels were studied by quantum chemical calculations at CCSD(T)/6-311++G(df,p)//MP2/6-311G(d,p) level. The calculated results fit with the experimental observations well.