芳烃硝化中的NO_2~++NO→NO_2+NO~+电子转移

用电子转移半经典理论,在谐振势近似下,导出交叉反应电子转移的动力学模型,在UHF/6-31G基组水平上,优化电子转移NO_2~++NO→NO_2+NO~+的碰撞络合物结构,用线性反应坐标研究了电子转移反应的透热势能面,反应活化能,电子转移矩阵元等动力学参量,对此交叉反应及相应的自交换反应体系NO_2~+/NO_2和NO~+/NO作动力学计算,得这3个基元步骤的活化能分别为81.4,128.8,和39.3KJ·mol~1.用过渡态结构参数估算溶剂重组对活化能的贡献,计算了300K时的速率常数.高的活化能垒可能影响NO_2~+在芳烃硝化中作为氧化剂的反应活性.     

基于密度泛函理论的CO2对NO异相还原影响的机理研究

为深入理解CO_2对NO异相还原的影响,本研究基于密度泛函理论,对CO_2参与下的煤焦-NO异相还原反应机理进行研究,并选取armchair苯环模型模拟焦炭表面。结构优化采用B3LYP-D3/6-31G(d)方法,单点能计算采用B3LYPD3/def2-TZVP方法。研究表明,CO_2吸附后形成的羰基与吸附态NO反应生成CO_2,继而CO_2脱附为后续NO吸附及N_2脱附提供邻近的碳活性位点。热力学研究表明,无CO_2参与条件下,反应放热853.9 kJ/mol,决速步能垒为297.0 kJ/mol;CO_2参与条件下,反应放出593.7 kJ/mol的热量,决速步能垒为214.1 kJ/mol。动力学研究表明,在298.15–1800 K的温度下,CO_2参与条件下的反应速率常数大于无CO_2参与条件下的反应速率常数。综合热力学和动力学研究结果发现,CO_2对NO的异相还原反应具有促进作用。     

CH3O·2+NO气相反应的密度泛函理论研究

用密度泛函方法分别研究了单态和三态 CH3 O·2 NO CH3 O· NO2 气相反应 .结果表明 ,反应中 NO进攻 CH3 O·2 经过了一个顺反异构化的过程 ,摘取 CH3 O·2 的端基氧 .整个反应是吸热反应 ,理论计算吸热值为 5 0 .93k J/ mol,单态为多通道多步骤反应 ,决定速度步骤的能垒为 1 90 .6 1 k J/ mol.而三态为单通道反应 ,其决定速度步骤的能垒为 1 6 3.31 k J/ mol.三态反应为最佳反应通道 .该反应的研究将为保护臭氧层及大气环境提供重要的理论依据 .     

n(H_2O)(n=1,2)在HO_2+NO→HNO_3反应中的催化机制研究

采用CCSD(T)/aug-cc-p VTZ//B3LYP/6-311+G(2df,2p)方法对n(H_2O)(n=0,1,2)参与HO_2+NO→HNO_3反应的微观机理和速率常数进行了研究.结果表明,由于水分子与HO_2形成的复合物(H_2O…HO_2,HO_2…H_2O)结合NO与水分子形成的复合物(NO…H_2O,ON…H_2O)的反应方式具有较高能垒和较低有效速率,其对HO_2+NO→HNO_3反应的影响远小于双体水(H_2O)2与HO_2(或NO)形成复合物然后再与另一分子反应物NO(或HO_2)的反应方式,因此n(H_2O)(n=1,2)催化HO_2+NO→HNO_3反应主要经历了HO_2…(H_2O)_n(n=1,2)+NO和NO…(H_2O)_n(n=1,2)+HO_22种反应类型.由于HO_2…(H_2O)_n(n=1,2)+NO反应的低能垒和高速率,HO_2…(H_2O)_n(n=1,2)+NO反应优于NO…(H_2O)_n(n=1,2)+HO_2反应.与此同时,由于计算温度范围内HO_2…H_2O+NO反应的有效速率常数比HO_2…(H_2O)2+NO反应对应的有效速率常数大了10~12数量级,可推测(H_2O)_n(n=1,2)催化HO_2+NO→HNO_3反应主要来自于单个水分子.此外,在216.7~298.6 K范围内水分子对HO_2+NO→HNO_3反应起显著的正催化作用,且随温度的升高有明显增大的趋势,在298.2 K时增强因子k'RW1/ktotal达到67.93%,表明在实际大气环境中水蒸气对HO_2+NO→HNO_3反应具有显著影响.     

石墨炭负载单原子铁催化剂非均相还原NO的微观作用机理：DFT研究

基于密度泛函理论和经典过渡态理论,探究了石墨炭负载单原子Fe催化剂(Fe/G)异相还原NO的微观机理,并对催化剂失活原因进行分析。结果表明,基于E-R机理,NO还原反应依次经历了N₂O形成与释放、N₂形成与释放四个阶段。而基于L-H机理,NO还原反应主要经历了N₂形成与释放两个阶段。在E-R机理作用下,NO分子以N,O-down结构吸附在Fe原子上发生的NO还原反应的控速步骤能垒值仅为15.5 kJ/mol,小于其余路径控速步骤能垒值。由能垒角度分析,Fe原子上残留的活性氧被还原的能垒值高于NO还原生成N₂的能垒值。NO分解后残留在Fe原子表面的活性氧抑制了NO的吸附与还原,Fe原子活性位的缺失导致催化剂的失活,单原子Fe的存在促进了NO还原反应的进行。由动力学角度分析,随着反应温度的升高,NO还原速率较活性氧转移速率提升更为显著。     

NCS自由基与NO反应动力学的理论研究

用量子化学密度泛函理论B3LYP/6-31+G^*和高级电子相关校正的偶合簇[CCSD(T)/6-311+G^*]方法,对NCS自由基与NO反应的机理和动力学进行了理论研究,得到了体系的势能面信息和可能的反应机理.计算了反应的热力学参数及反应能垒.采用传统过渡态理论计算了各反应通道的速率常数.研究结果表明,NCS自由基与NO反应中存在4个反应通道,产物分别为OCS+N₂,CS+N₂O,ONS+CN和ONCNS.从能量变化和反应速率两方面考虑,NCS+NOOCS+N₂应为主反应通道.     

NO2和HSO反应的机理及动力学研究

本文采用CCSD(T)/aug-cc-pVTZ//B3LYP/aug-cc-pVTZ方法构建了NO2 + HSO反应的单、三重态势能面,并对主通道速率常数进行了计算。研究结果表明,该反应在单[R1(HN(O)O + 1SO)、R2(cis-HONO + 1SO)和R3 (trans-HONO + 1SO)]、三重态[R6(HN(O)O + 3SO)、R7(cis-HONO + 3SO)和R8(trans-HONO + 3SO)]均存在3条抽氢反应通道,在单[R4(NO + HS(O)O)和R5(H + SO2 + NO)]、三重态[R9(HS(O)O + NO)和R10(H + SO2 + NO)]均存在两条抽氧通道,其中单重态抽氢通道R2 (cis-HONO + 1SO)是NO2 + HSO反应主通道。利用传统过渡态理论(TST)并结合Wigner校正,计算了上述10条通道在200 ~ 1000 K温度范围内的速率常数。计算结果表明,NO2 + HSO反应主通道在298 K时的速率常数(7.78×10-13cm3?molecule-1?s-1)与实验值(9.6×10-12 cm3?molecule-1?s-1)相吻合。此外,水分子影响主通道R2(cis-HONO + 1SO)经历了NO2 + H2O…HSO和 NO2 + H2O…HSO(HSO + NO2…H2O)两条反应通道,且两条通道的能垒分别比R2升高了49.97和20.43 kcal?mol-1,说明在实际大气环境中水分子对NO2 + HSO反应几乎没有影响。     

CH2SH与NO2双自由基反应机理的理论研究

在B3LYP/6-311＋＋G(2df,p)水平上优化了标题反应驻点物种的几何构型, 并在相同水平上通过频率计算和内禀反应坐标(IRC)分析对过渡态结构及连接性进行了验证. 采用双水平计算方法HL//B3LYP/6-311＋＋G(2df,p)对所有驻点及部分选择点进行了单点能校正, 构建了CH2SH＋NO2反应体系的单重态反应势能剖面. 研究结果表明, CH2SH与NO2反应体系存在4条主要反应通道, 两个自由基中的C与N首先进行单重态耦合, 形成稳定的中间体HSCH2NO2 (a). 中间体a经过C—N键断裂和H(1)—O(2)形成过程生成主要产物P1 (CH2S＋trans-HONO), 此过程需克服124.1 kJ•mol－1的能垒. 中间体a也可以经过C—N键断裂及C—O键形成转化为中间体HSCH2ONO (b), 此过程的能垒高达238.34 kJ•mol－1. b再经过一系列的重排异构转化得到产物P2 (CH2S＋cis-HONO), P3 (CH2S＋HNO2)和P4 (SCH2OH＋NO). 所有通道均为放热反应, 反应能分别为－150.37, －148.53, －114.42和－131.56 kJ•mol－1. 标题反应主通道R→a→TSa/P1→P1的表观活化能为－91.82 kJ•mol－1, 此通道在200～3000 K温度区间内表观反应速率常数三参数表达式为kCVT/SCT＝8.3×10－40T4.4 exp(12789.3/T) cm3•molecule－1•s－1.     

H+CH3NO2H2+CH2NO2反应途径和变分速率常数计算研究

采用MP2(FULL)/6-311G**从头算方法, 优化了H+CH3NO2H2+ CH2NO2反应的过渡态结构, 得出该反应的正逆反应的活化位垒分别是82.73和57.14 kJ*mol-1. 沿IRC分析指出该反应是一个H-H键生成和C-H键断裂的协同反应, 而且在反应途径上存在一个引导反应进行的振动模式, 这一反应模式引导反应进行的区间在-0.7～0.2( amu)1/2*a0之间; 在1 000～1 400 K温度范围内, 运用变分过渡态理论(CVT), 计算了该反应的速率常数, 计算结果与实验相一致.     

C_2(a~3Π_u)自由基与若干不饱和碳氢化合物反应的温度效应

运用脉冲激光光解-激光诱导荧光(PLP-LIF)的方法研究了C2(a3Πu)自由基与若干不饱和碳氢化合物(C2H4(k1),C2H2(k2),C3H6(k3)和2-C4H8(k4))气相反应的温度效应.在298-673 K的温度范围内,获得了这些反应的双分子反应速率常数.获得的速率常数可以用Arrhenius公式表达如下:k1(T)=(4.53±0.05)×10-11exp[(196.41±5.20)/T],k2(T)=(3.94±0.04)×10-11exp[(143.04±4.28)/T],k3(T)=(7.96±0.17)×10-11exp[(185.10±8.86)/T],k4(T)=(1.04±0.02)×10-10exp[(180.34±7.67)/T],误差为±2σ.由获得的双分子反应速率常数及其所呈现的负温度效应,在298-673 K温度范围内,C2(a3Πu)自由基和这些不饱和碳氢化合物的反应遵循加成机理.     

低温等离子体转化NO/O2/N2气氛中NO的实验研究

通过建立低温等离子体实验系统, 研究了介质阻挡放电型低温等离子体反应器作用于NO/O2/N2混合气体系时, NO, O2初始浓度对NO的转化效率的影响以及NOx, O3浓度随能量密度的变化关系. 低温等离子体作用于NO/O2/N2混合气体系时, NO同时发生氧化还原反应, 氧化反应占主导地位, 大部分NO转化为NO2; NO转化率随O2, NO初始浓度增大而降低, 能量密度在450～600 J/L时转化率较高; 产生的O3浓度随能量密度的增大呈先增后减的趋势.     

Electron transfer NO 2 + +NO→N02+NO+ in aromatic nitration

A simple model for computing the electron transfer rate constant of a cross-reaction has been proposed in the framework of semiclassical theory and employed to investigate the electron transfer system NO ₂ ⁺ /NO. The encounter complex of electron transfer NO ₂ ⁺ +NO→N0₂+NO⁺ has been optimized at the level of UHF/6-31G. In the construction of diabatic potential energy surfaces the linear coordinate was used and the kinetic quantities, such as the activation energies and the electron transfer matrix elements, have been obtained. For comparison, the related selfexchange reactlon systems NO ₂ ⁺ /NO₂ and NO⁺/NO were kinetically investigated. The calculated activation energies for the electron transfer reactions of systems NO ₂ ⁺ /NO, NO ₂ ⁺ /NO₂, and NO⁺/NO are 81.4, 128.8, and 39.8 kJ.mol^-1, respectively. With the solvent effect taken into account, the contribution of solvent reorganization to the activation energy has been estimated according to the geometric parameters of the transition states. The obtained rate constants show that the activity of NO ₂ ⁺ as an oxidizing reagent in the aromatic nitration will be greatly decreased due to a high activation barrier contributed mainly from the change of bond angle ONO.     

Reaction Mechanism and Kinetics for HCCO Radical with NO

The mechanism and dynamical properties for the reaction of HCCO radicals with NO were investigated theoretically. The minimum energy paths(MEP) of the reaction were calculated by using the density functional theory(DFT) at the B3LYP/6-311 G^** level, and the energies along the MEP were further refined at the QCISD(T)/6-311 G^** level. It is found that the reaction mechanism of the title reaction involves three channels, producing HCNO CO, HONC CO and HCN CO2 products, respectively. Channel 1 is the most favorable path. The rate constant for channel 1 were calculated over a temperature range of 800-2500 K by using the canonical variational transition-state theory(CVT). The rate constant for the main path is negatively dependent on temperature, which is a characteristic of radical reactions with negative activation energy, and the variational effect for the rate constant calculation is small in the whole temperature range.     

H原子和SiH2Cl2抽提反应的理论研究

对H+SiH2Cl2反应进行了详细的理论研究,理论证明了抽提氢的通道是唯一可行的反应通道。并在从头算给出的电子结构信息基础上,用变分过渡态理论(CVT)加小曲率隧道效应校正(SCT)等方法对该反应进行了直接的动力学研究,得到该反应的理论速率常数,并详细讨论了各动力学参数沿反应坐标的变化。在较宽的温度范围内,反应速率常数表现出非Arrhenius行为,用三参数公式似合了速-温关系式,为k(T)=(1.32×10^-22)T^3.67exp(-26/T)。理论计算的速率常数与实验数值符合得很好。     

Kinetics and mechanism of the NCN + NO2 reaction studied by experiment and theory

The rate constant for the NCN + NO 2 reaction has been measured by a laser photolysis/laser-induced fluorescence technique in the temperature range of 260-296 K at pressures between 100 and 500 Torr with He and N 2 as buffer gases. The NCN radical was produced from the photolysis of NCN 3 at 193 nm and monitored by laser-induced fluorescence with a dye laser at 329.01 nm. The rate constant was found to increase with pressure but decrease with temperature, indicating that the reaction occurs via a long-lived intermediate stabilized by collisions with buffer gas. The reaction mechanism and rate constant are also theoretically predicted for the temperature range of 200-2000 K and the He and N 2 pressure range of 10 (-4) Torr to 1000 atm based on dual-channel Rice-Ramsperger-Kassel-Marcus (RRKM) theory with the potential energy surface evaluated at the G2M//B3LYP/6-311+G(d) level. In the low-temperature range (<700 K), the most favorable reaction is the barrierless association channel that leads to the intermediate complex (NCN-NO 2). At high temperature, the direct O-abstraction reaction with a barrier of 9.8 kcal/mol becomes the dominant channel. The rate constant calculated by RRKM theory agrees reasonably well with experimental data.     

羟氨(H2NOH)重排反应的理论研究

羟氨H_2NOH是人们所熟知的分子,但至今还没有确切的实验证据证实有氨氧化物H_2NO的存在,尽管其取代物R_3NO已被分离出。鉴于类羟氨R_2NOH和N-氧化物在生物学上的重要意义,研究H_2NOH和H_3NO的结构以及二者重排反应的动力学行为就成了一个重要课题。本文用内禀反应坐标方法对此反应进行了反应路径解析,并给出了沿反应途径上的振动频率相关。     

Theoretical study on the kinetics and mechanism for the reaction of FCO with NO

The radical reaction mechanism of FCO + NO on the ground electronic state energy surface has been studied at the G2M level of theory based on the geometric parameters optimized at the B3LYP/6-311+G(d) level of theory. The two kinds of reaction pathways include the direct fluorine abstraction channel producing CO + FNO and the association channel forming the FC(O)NO complex. The former has a distinct barrier of 8.9 kcal mol(-1), while the latter is a barrierless association process. The rate constant of this reaction system in the temperature range 200-3000 K has been calculated by the microcanonical VTST/RRKM theory. The theoretical result shows that the predicted total rate constants exhibit a negative-temperature dependence and positive-pressure effect at lower temperatures. Under the experimental conditions, the predicted values are in good agreement with the experimental results. In addition, the predicted branching ratios clearly indicate that the dominant product channel is the formation of FC(O)NO at low temperatures and FNO + CO at high temperatures (>500 K).     

Mechanism and Kinetics for the Reaction of NCS and OH Radicals

The mechanism and dynamical properties for the reaction of NCS and OH radicals have been investigated theoretically. The minimum energy paths (MEP) of the reaction were calculated using the density functional theory(DFT) at the B3LYP/6-311 G^** level, and the energies along the MEP were further refined at the QCISD(T)/6-311 G^** level. As a result, the reaction mechanism of the title reaction involves three channels, producing HCS NO and HNC SO products, respectively. Path Ⅰ and path Ⅱ are competitive, with some advantages for path Ⅰ in kinetics. As for path Ⅲ, it looks difficult to react for its high energy barrier. Moreover, the rate constant have been calculated over the temperature range of 8190-2500K using canonical variational transition-state theory (CVT). It was found that the rate constants for both path Ⅰ and path Ⅱ are negatively dependent on temperature, which is similarwith the experimental results for reactions of NCS with NO and NO2, and the variational effect for the rate constant calculation olavs an important role in whole temperature range.     

Spin-orbit effect in the energy pooling reaction O2(a 1Delta)+O2(a 1Delta)-->O2(b 1Sigma)+O2(X 3Sigma)

Five-dimensional nonadiabatic quantum dynamics studies have been carried out on two new potential energy surfaces of S(2)((1)A(')) and T(7)((3)A(")) states for the title oxygen molecules collision with coplanar configurations, along with the spin-orbit coupling between them. The ab initio calculations are based on complete active state second-order perturbation theory with the 6-31+G(d) basis set. The calculated spin-orbit induced transition probability as a function of collision energy is found to be very small for this energy pooling reaction. The rate constant obtained from a uniform J-shifting approach is compared with the existing theoretical and experimental data, and the spin-orbit effect is also discussed in this electronic energy-transfer process.