三氟乙烷与氟原子氢提取反应的动力学研究

采用双水平直接动力学方法研究了氢提取反应CH3CF3+F→CH2CF3+HF的反应机理.首先用MPW1K/6-311+G(d,p)方法优化了驻点的几何构型,并在相同水平上进行了频率分析,利用内禀反应坐标理论获得了最小的反应能量途径;随后,为了得到更准确的能量信息,采用MCG3-MPWPW91//MPW1K方法进行了单点能量校正;最后,根据变分过渡态理论计算了该反应在200² 000K温度范围内的速率常数.结果表明,理论计算值与已有的实验值吻合.     

三维含时量子散射研究H + CIH体系

用三维含时量子散射理论模拟了H+CIH体系在BW2,mBW2,G3势能面上的动力学行为,其计算结果表明,振动量子态对反应几率影响很大;势能面的地形对转动量子态如何影响反应几率起重要作用;反应几率表现出“黄金规则”,此外,BW2,mBW2势能面上的反应几率几乎相同,而G3势能面上的反应几率较前者低,大概由于G3的势垒高的缘故。     

基于量子波包方法的态-态分辨反应散射动力学计算

本文回顾了最近十几年利用量子波包方法研究气相分子反应散射动力学的工作进展,特别是在态-态分辨水平上的工作进展。比较详细地讨论了目前存在的利用量子波包方法计算态-态微分截面的几种方法。目前态-态分辨的波包动力学计算可以精确地预测三原子和四原子分子反应散射的各种信息,文章最后对几个典型的利用波包方法在态-态分辨水平上研究过的三原子和四原子反应散射体系做了讨论。     

氢原子共线交换反应的动力学计算I.Cl与HCl反应几率的振荡现象研究

我们利用超球坐标对共线Cl+HCl(V-3)→ClH(V'≤3)+Cl作了一维精确量子计算,计算所用势能面是LEPS型,Et=-3.23KJ/mol, 得到了态态反应几率等动力学信息, 通过分析结果发现, 反应是振动绝热的, 即以对角(V'-V')反应几率为主,非对角(V' V')反应几率小于0.1, 反应几率随总能量表现出强裂地振荡, 在有阱的势能面上动力学共振增强。     

共线量子散射方法研究D+CID体系

用共线量子散射方法计算D+CID体系的反应几率和传能几率。发现存在很强的振荡现象。体系的碰撞中间态的寿命的计算结果为fs-ps数量级。当某一反应通道打开时,在能量阈值附近通常都伴随着一些长寿命的碰撞中间态。这一点该体系中表现很比较明显。     

氢原子共线交换反应的动力学计算I.Cl与HCl反应几率的振荡现象研究

我们利用超球坐标对共线Cl+HCl(V-3)→ClH(V'≤3)+Cl作了一维精确量子计算,计算所用势能面是LEPS型,Et=-3.23KJ/mol, 得到了态态反应几率等动力学信息, 通过分析结果发现, 反应是振动绝热的, 即以对角(V'-V')反应几率为主,非对角(V' V')反应几率小于0.1, 反应几率随总能量表现出强裂地振荡, 在有阱的势能面上动力学共振增强。     

量子反应散射的动力学李代数方法

用动力学李代数方法描述了量子反应散射问题 .对共线交换反应A BC→AB C ,得到了含有主要动力学参数的反应跃迁几率的解析表达式 .计算了共线反应散射过程H H2 (n =0 )→H2 (n′ =0 ) H的反应跃迁几率 .结果表明 ,动力学李代数方法对计算反应几率是非常有效的 .     

量子反应散射的非弹性散射表达式

对于原子-双原子分子的反应散射采用核间距作坐标。经过坐标的质量标度化,坐标旋转及换成超球坐标,则量子反应散射具有与非弹性散射相似的表达式。在此描述下,反应体系自然地、均匀地由反应态转化为产物态,避免了不同排列通道间的坐标变换。     

化学反应散射共振态的实验检测与理论模拟

化学反应中的散射共振态（或称反应性共振）控制着化学反应的分支比、产物的态分布及空间分布等。反应性共振的实验检测分为间接法和直接法。从理论上,一是构造反应体系的势能面,从势能面过渡态的结构来研究散射共振态;二是计算态-态反应动力学,尤其是用寿命矩阵来研究散射共振态。本文介绍反应性散射共振态的实验检测及理论模拟方法,并对今后的发展动向作出展望。     

A quantum scattering study of collinear state-testate reaction probabilities for the F + H2(v) → HF(v') + H system

A new quantum scattering approach (linear combination of arrangement channels-scattering wavefunction, LCAC-SW) proposed by Deng and his co-workers is used to calculate collinear state-to-state reaction probabilities for the F + H₂(v) → HF(v') + H system. Several interesting problems such M threshold energy, compound states and enhance by translational energy of the reactants and the vibration excitation of products are discussed and they are compared with other theoretical investigations reported in the literature. It is shown that the LCAC-SW approach is the successful one of quantum scattering methods.     

Energy resonance and inverse population of the product vibrational states for the reaction F + H2(v = 0) → HF(v′) + H,LCAC‐SW theoretical quantum scattering study

LCAC‐SW (linear combination of arrangement channel‐scattering wavefunction) method was used to calculate collinear state‐to‐state reaction probabilities for the reaction F + H₂(v = 0) → HF(v′) + H on the 6SEC potential energy surface. The results show that reaction probabilities P₀₂ and P₀₃ [i. e., v′ = 2,3 for reaction F + H₂ (v = 0) + HF(v′) + H] are primary, the population of product vibrational states is inverse and the reaction probabilities are oscillatory with collision energies, i.e., there is energy resonance in this reaction, which agrees with a new experiment.     

Quantum scattering LCAC-SW theory studies on reaction probabilities of three-dimensional H+H_2(υ,j)→H_2(υ′, j′)+H reaction

ＩｎｌｉｇｈｔｏｆＫｏｈｎｖａｒｉａｔｉｏｎｔｈｅｏｒｙ,Ｍｉｌｌｅｒｃｏｎｓｔｒｕｃｔｅｄａｎｅｗｑｕａｎｔｕｍｒｅａｃｔｉｖｅｓｃａｔｔｅｒｉｎｇｍｅｔｈｏｄ:ｔｈｅＳｍａｔｒｉｘｖａｒｉａｔｉｏｎｍｅｔｈｏｄ[1,2],ｗｈｉｃｈｉｓａｔｙｐｉｃａｌｏｎｅｉｎｗｈｉｃｈａｌｇｅｂｒａｉｃｍｅｔｈｏｄｉｓｕｓｅｄｔｏｓｏｌｖｅｄｉｒｅｃｔｌｙｔｈｅＳｃｈｒｄｉｎｇｅｒｅｑｕａｔｉｏｎ.Ｂｅｃａｕｓｅｔｈｅｍｅｔｈｏｄｉｎｃｌｕｄｅｓｎａｔｕｒａｌｌｙｔｈｅｂｏｕｎｄａｒｙｃｏｎｄｉｔｉｏｎｓ,ｔｈｅｗ…     

离子对生成反应截面的量子散射理论研究

将Miller的S-矩阵变分法推广到离子对生成反应动力学的研究。M＋X~2→M^+＋X~2^-反应体系包括共价态(M＋X~2)和离子态(M^+＋X~2^-)两个势能面及其交叉效应,本文在此两态模型下导出了生成截面公式。在矩阵元计算中,平动波函数采用分布Gauss基作展开。作为上述公式的应用,对Cs＋O~2→Cs^+＋O~2^-反应体系作了数值计算并取得了满意结果。     

1-氟-1,1- 二氯乙烷与氟原子反应的理论研究

利用密度泛函理论研究了CH3CCl2F与F原子的反应机理.在MPW1K水平下计算了反应物、过渡态和产物的几何构型和频率,并进一步利用内禀反应坐标理论获得了反应的最小能量路径;在G3(MP2)水平下对所有驻点进行了单点能量校正.结果表明,CH3CCl2F与F原子的反应存在两个H迁移反应通道:CH2H′CCl 2F+F→C...     

Quantum scattering LCAC-SW theory studies on reaction probabilities of three-dimensional H + H2 (v, j) → H2 (v′, j′) + H reaction

Upon the Liu, Siegbahn, Truhlar, Horowitz (LSTH) potential energy surface, the reaction probabilities of the three-dimensional (3-D) state-to-state H + H₂ (v, j) →H ₂(v′, j′) + H reaction are calculated with the linear combination of arrangement channels-scattering wavefunction (LCAC-SW) method. In the calculation, the vibration function of H₂ and the radial propagating wave functions are expanded by the real Gauss functions. The calculated threshold energy and the resonating structure are consistent with the results of the accurate quantum scattering calculations, which shows the accuration, simplicity and practicability of the LCAC-SW method. Project supported by the National Natural Science Fondation of China and the Doctoral Foundation of the State Education Commission of China.     

Exact quantum calculations on the collinear hydrogen atom transfer reaction I. Study on oscillations of the reaction probabilities of Cl + HCl

1-D quantum calculations of reaction probabilities have been carried out for the collinear reaction Cl + HCl (v≤3)→ClH (v′≤3) + Cl using hyperspherical coordinates. An LEPS potential energy surface with a shallow well depth of ?3.22 KJ/mol has been used in the calculations. The state-to-state reaction probabilities have been calculated. According to the results obtained we found that the diagonal (v=v′) reaction probabilities dominate over the off-diagonal (v≠v′) reaction probabilities and the largest off-diagonal reaction probabilities are smaller than 0.1. The reaction probabilities show oscillation as a function of energy. Dynamic resonances strengthen for the potential energy surface with a well.     

LCAC-SW quantum scattering dynamic study on the ion-pair formation process

LCAC-SW method has been extended to study the reaction dynamics for ion-pair formation processes. M X2→-M X2- reaction system involves two potential energy surfaces, i.e., the covalence state (M X2) and the ionic state (M X2-) and their crossing effect. The working equations for calculating state-to-state probability have been derived based on the above two-state model. Satisfied results of collinear state-to-state probabilities for K I2→K I2- ion-pair formation system have been obtained.