2,2-二氟-1-溴-1-锂乙烯的结构及重排反应的理论研究

用量子化学中的密度泛函DFT方法,在B3LYP／6-31G(d,p)水平上研究了2,2-二氟-1-溴-1-锂乙烯F2C—CLiBr的结构．结果表明,F2C=CLiBr有2种平衡结构,其中只有1种是稳定的．对稳定的平衡结构,找到了其可能的重排反应过渡态,根据计算得到的重排反应势垒,解释了氟原子只从溴原子对位发生迁移的原因．     

不饱和类卡宾H_2C=CLiF的结构及氢迁移反应的DFT研究

用量子化学中的密度泛函DFT方法，在B3LYP/6-311G~*水平上研究了不饱和类 卡宾H_2C=CLiF的结构。结果表明，只有1种平衡结构是稳定的。对稳定的平衡结构 ，找到了分子内氢迁移反应的过渡态，并计算了不同温度下不饱和类卡宾 H_2C=CLiF的平均寿命τ，在200 K时，τ = 7.9 d，在300 K仅为τ = 2.4 s。     

不饱和类卡宾H_2C=CLiF的结构及氢迁移反应的DFT研究

用量子化学中的密度泛函DFT方法,在B3LYP/6-311G~*水平上研究了不饱和类 卡宾H_2C=CLiF的结构。结果表明,只有1种平衡结构是稳定的。对稳定的平衡结构 ,找到了分子内氢迁移反应的过渡态,并计算了不同温度下不饱和类卡宾 H_2C=CLiF的平均寿命τ,在200 K时,τ = 7.9 d,在300 K仅为τ = 2.4 s。     

钛与3，5－二溴水杨基荧光酮配位反应的弛豫动力学研究

用跳浓弛豫法测定了微扰体系在不同浓度［Ｔｉ￣（４＋）］时的弛豫时间τ，拟定了合理的反应机理，并根据此机理导出了１／τ的函数表达式为１／τ＝ｋ［Ｈ４Ｒ］＿０／［Ｈ３Ｏ￣＋］＿０－４ｋ·Ａ∞／ε·［Ｈ３Ｏ￣＋］０，获得了配位反应的表现稳定常数Ｋ、表观速率常数ｋ及摩尔吸光系数ε；其中所得稳定常数Ｋ的值与用平衡移动法获得的结果相吻合，进一步证明了所拟机理的合理性。     

锂氟类硅烯与乙烯加成反应的理论研究

用从头计算方法研究了锂氟类硅烯与乙烯的加成反应Ｈ_２ＳｉＬｉＦ＋Ｃ_２Ｈ_４→Ｈ_２ＳｉＣ_２Ｈ４＋ＬｉＦ．该反应的过渡态和类卡宾与乙烯的反应相似。反应前后的能量差经零点能校正后仅为－２．４ｋＪ／ｍｏｌ（ＭＰ２／６－３１Ｇ￣＊／／６－３１Ｇ￣＊）．本文分析了孩反应的热力学和动力学性质，计算了反应热力学函数的变化、平衡常数、Ａ因子以及速率常数。     

2，3－二甲基－1－对氯苯磺酰基咪唑啉盐与邻氨基苯酚反应的量子化学研究

用量子化学方法对叶酸辅酶模型化合物2，3－二甲基－1－对氯苯磺酰基咪唑 啉盐与邻氨基苯酚的反应进行了理论研究。结果表明，咪唑啉环有两种开环方式， 反应可以通过两种途径实现，得到较稳定的中间体或者实现一碳单元的完全转移。 通过优化计算所有步骤的中间体和过渡态的结构可知，各个中间体和过渡态具有不 同的构型、构象，有些过程的构象变化是进行下一步反应所必需的，在所有过程中 质子转移步骤过渡态的能量最高，是反应的限速步骤。     

微量热法研究单底物酶促反应的热力学和动力学性质及过渡态的分析

用LKB-2107型微量热系统, 测定了漆酶催化氧化3, 4-二羟基苯甲醛、邻甲氧基酚、邻苯三酚、3, 4, 5-三羟基苯甲酸反应的热谱图, 利用热谱图计算了米氏常数(Km)、反应速率常数(k2)和热力学参数(ΔrHm, ΔG0, ΔT^≠, Ea, ΔST^≠)。并应用过渡态理论对其催化过程进行了分析。结果表明: 稳定过渡态结构有利于酶促反应, 酶-底物在反应物时相互作用仅仅是降低酶的催化效率。提出两种可能提高酶催化效率的方法。由活化熵(ΔST)<0得出酶-底物在过渡态的结构较酶-底物复合物的结构更为有序。     

8-二甲基-7-甲氧基-5-烯-壬腈氧化物环加成反应机理

用过渡态理论和AM1方法，对8－二甲基－7－甲氧基－5－烯－壬腈氧化物分子内环加成反应机理进行了研究。结果表明，存在两种产物的平行反应，对两个反应的速率常数比值的计算，得到反式和顺式的产率比为90.5:9.5，与实验产率比值（≥85：15）结果接近。标题物立体专一选择性由活化焓和活化熵共同决定。     

CH3(2A′)自由基与臭氧反应机理的量子化学研究

用量子化学UMP2方法，在6-311++G**基组水平上研究了CH3(2A′)自由基与臭氧反应机理，全参数优化了反应过程中反应物、中间体、过渡态和产物的几何构型，在UQCISD(T)/6-311++G**水平上计算了它们的能量；并对它们进行了振动分析，以确定中间体和过渡态的真实性；同时应用经典过渡态理论计算了反应的速率常数，并与实验值进行了比较, CH3自由基与臭氧反应速率常数的理论计算结果为: 4.73×10－14 cm3•molecule－1•s－1，与实验报导的结果(k=2.52×10－14 cm3•molecule－1•s－1)很接近，同时发现CH3(2A′)自由基与O3的反应是强放热反应.     

乙烯和丙烯自由基共聚反应的多尺度模拟模型

结合量子化学和传统过渡态理论计算了乙烯和丙烯自由基聚合反应的速率常数.利用速率常数定义了聚合反应几率(Pijl),构造了乙烯和丙烯共聚合反应的粗粒化动力学模拟模型,并利用该模型研究了不同组成比的乙烯和丙烯的共聚合反应.发现反应速率常数和链端自由基周围的单体浓度都影响链上组分的序列分布.     

Kinetics of the reaction of methyl radical with hydroxyl radical and methanol decomposition

The CH3 + OH bimolecular reaction and the dissociation of methanol are studied theoretically at conditions relevant to combustion chemistry. Kinetics for the CH3 + OH barrierless association reaction and for the H + CH2OH and H + CH3O product channels are determined in the high-pressure limit using variable reaction coordinate transition state theory and multireference electronic structure calculations to evaluate the fragment interaction energies. The CH3 + OH --> 3CH2 + H2O abstraction reaction and the H2 + HCOH and H2 + H2CO product channels feature localized dynamical bottlenecks and are treated using variational transition state theory and QCISD(T) energies extrapolated to the complete basis set limit. The 1CH2 + H2O product channel has two dynamical regimes, featuring both an inner saddle point and an outer barrierless region, and it is shown that a microcanonical two-state model is necessary to properly describe the association rate for this reaction over a broad temperature range. Experimental channel energies for the methanol system are reevaluated using the Active Thermochemical Tables (ATcT) approach. Pressure dependent, phenomenological rate coefficients for the CH3 + OH bimolecular reaction and for methanol decomposition are determined via master equation simulations. The predicted results agree well with experimental results, including those from a companion high-temperature shock tube determination for the decomposition of methanol.     

Theoretical studies of the reactions of O(~3p) with halogenated methyl (Ⅰ)——Reaction mechanism of the O(~3p) CH_2Cl reaction

The reaction of O(~3P) with CH_2Cl radical has been studied using ab initio molecular orbital theory. G2 (MP2) method is used to calculate the geometrical parameters, vibrational frequencies and energies of various stationary points on the potential energy surface. The reaction mechanism is revealed. The addition of O(~3P) with CH_2Cl leads to the formation of an energy rich intermediate OCH_2Cl which can subsequently undergo decomposition or isomerization to the final products. The calculated heat of reaction for each channel is in agreement with the experimental value. The production of H CHClO and Cl CH_2O are predicted to be the major channels. The overall rate constants are calculated using transition state theory on the basis of ab initio data. The rate constant is pressure independent and exhibits negative temperature dependence at lower temperatures, in accordance with the experimental results.     

Towards the experimental decomposition rate of carbonic acid (H2CO3) in aqueous solution

Dry carbonic acid has recently been shown to be kinetically stable even at room temperature. Addition of water molecules reduces this stability significantly, and the decomposition (H2CO3 + nH2O --> (n+1)H2O + CO2) is extremely accelerated for n = 1, 2, 3. By including two water molecules, a reaction rate that is a factor of 3000 below the experimental one (10 s(-1)) at room temperature was found. In order to further remove the gap between experiment and theory, we increased the number of water molecules involved to 3 and took into consideration different mechanisms for thorough elucidation of the reaction. A mechanism whereby the reaction proceedes via a six-membered transition state turns out to be the most efficient one over the whole examined temperature range. The determined reaction rates approach experimental values in aqueous solution reasonably well; most especially, a significant increase in the rates in comparison to the decomposition reaction with fewer water molecules is found. Further agreement with experiment is found in the kinetic isotope effects (KIE) for the deuterated species. For water-free carbonic acid, the KIE (i.e., kH2CO3/kD2CO3) for the decomposition reaction is predicted to be 220 at 300 K, whereas it amounts to 2.2-3.0 for the investigated mechanisms including three water molecules. This result is therefore reasonably close to the experimental value of 2 (at 300 K). These KIEs are in much better accordance with the experiment than the KIE for decomposition with fewer water entities.     

Preparation and thermal studies of self-crosslinked terpolymer derived from 4-acetylpyridine oxime, formaldehyde and acetophenone

Terpolymer (4-APOFA) has been synthesized using the monomer 4-acetylpyridine oxime, formaldehyde and acetophenone in 1:5:1 molar proportion. The structure of 4-APOFA terpolymer has been elucidated based on various physicochemical techniques, i.e., FT-IR, ¹H NMR, Pyrolyis GC/MS and viscosity average molecular weight. The glass transition temperature (T_g) and thermal stability of terpolymer have been determined by DSC. The activation energy of the thermal reaction has been determined with differential scanning calorimetry using Kissinger method. The apparent activation energies (E_a) of each step during thermodegradation have been determined using Flynn-Wall-Ozawa method. The type of solid-state mechanism has been established by Craido method. From the calculation, the solid-state thermal mechanism is proposed to be D₃ (three-dimensional diffusion) at initial decomposition state and F₁ (random nucleation with one nucleus on the individual particle) at second decomposition state for 4-APOFA. It has also been shown to possess excellent antimicrobial activities as compared to other cationic resins.     

Thermal degradation kinetics of the biodegradable aliphatic polyester, poly(propylene succinate)

The preparation of the biodegradable aliphatic polyester poly(propylene succinate) (PPSu) using 1,3-propanediol and succinic acid is presented. Its synthesis was performed by two-stage melt polycondensation in a glass batch reactor. The polyester was characterized by gel permeation chromatography, ¹H NMR spectroscopy and differential scanning calorimetry (DSC). It has a number average molecular weight 6880 g/mol, peak temperature of melting at 44 °C for heating rate 20 °C/min and glass transition temperature at −36 °C. After melt quenching it can be made completely amorphous due to its low crystallization rate. According to thermogravimetric measurements, PPSu shows a very high thermal stability as its major decomposition rate is at 404 °C (heating rate 10 °C/min). This is very high compared with aliphatic polyesters and can be compared to the decomposition temperature of aromatic polyesters. TG and Differential TG (DTG) thermograms revealed that PPSu degradation takes place in two stages, the first being at low temperatures that corresponds to a very small mass loss of about 7%, the second at elevated temperatures being the main degradation stage. Both stages are attributed to different decomposition mechanisms as is verified from activation energy determined with isoconversional methods of Ozawa, Flyn, Wall and Friedman. The first mechanism that takes place at low temperatures is auto-catalysis with activation energy E = 157 kJ/mol while the second mechanism is a first-order reaction with E = 221 kJ/mol, as calculated by the fitting of experimental measurements.     

Shock tube and theoretical studies on the thermal decomposition of propane: evidence for a roaming radical channel

The thermal decomposition of propane has been studied using both shock tube experiments and ab initio transition state theory-based master equation calculations. Dissociation rate constants for propane have been measured at high temperatures behind reflected shock waves using high-sensitivity H-ARAS detection and CH(3) optical absorption. The two major dissociation channels at high temperature are C(3)H(8) → CH(3) + C(2)H(5) (eq 1a) and C(3)H(8) → CH(4) + C(2)H(4) (eq 1b). Ultra high-sensitivity ARAS detection of H-atoms produced from the decomposition of the product, C(2)H(5), in (1a), allowed measurements of both the total decomposition rate constants, k(total), and the branching to radical products, k(1a)/k(total). Theoretical analyses indicate that the molecular products are formed exclusively through the roaming radical mechanism and that radical products are formed exclusively through channel 1a. The experiments were performed over the temperature range 1417-1819 K and gave a minor contribution of (10 ± 8%) due to roaming. A multipass CH(3) absorption diagnostic using a Zn resonance lamp was also developed and characterized in this work using the thermal decomposition of CH(3)I as a reference reaction. The measured rate constants for CH(3)I decomposition agreed with earlier determinations from this laboratory that were based on I-atom ARAS measurements. This CH(3) diagnostic was then used to detect radicals from channel 1a allowing lower temperature (1202-1543 K) measurements of k(1a) to be determined. Variable reaction coordinate-transition state theory was used to predict the high pressure limits for channel (1a) and other bond fission reactions in C(3)H(8). Conventional transition state theory calculations were also used to estimate rate constants for other tight transition state processes. These calculations predict a negligible contribution (<1%) from all other bond fission and tight transition state processes, indicating that the bond fission channel (1a) and the roaming channel (1b) are indeed the only active channels at the temperature and pressure ranges of the present experiments. The predicted reaction exo- and endothermicities are in excellent agreement with the current version of the Active Thermochemical Tables. Master equation calculations incorporating these transition state theory results yield predictions for the temperature and pressure dependence of the dissociation rate constants for channel 1a. The final theoretical results reliably reproduce the measured dissociation rate constants that are reported here and in the literature. The experimental data are well reproduced over the 500-2500 K and 1 × 10(-4) to 100 bar range (errors of ～15% or less) by the following Troe parameters for Ar as the bath gas: k(∞) = 1.55 × 10(24)T(-2.034) exp(-45?490/T) s(-1), k(0) = 7.92 × 10(53)T(-16.67) exp(-50?380/T) cm(3) s(-1), and F(c) = 0.190 exp(-T/3091) + 0.810 exp(-T/128) + exp(-8829/T).     

Calculations on the rate of the ion-molecule reaction between NH3+ and H2

The rate coefficient for the ion-molecule reaction NH3(+) + H2 --> NH4(+) + H has been calculated as a function of temperature with the use of the statistical phase space approach. The potential surface and reaction complex and transition state parameters used in the calculation have been taken from ab initio quantum chemical calculations. The calculated rate coefficient has been found to mimic the unusual temperature dependence measured in the laboratory, in which the rate coefficient decreases with decreasing temperature until 50-100 K and then increases at still lower temperatures. Quantitative agreement between experimental and theoretical rate coefficients is satisfactory given the uncertainties in the ab initio results and in the dynamics calculations. The rate coefficient for the unusual three-body process NH3(+) + H2 + He --> NH4(+) + H + He has also been calculated as a function of temperature and the result found to agree well with a previous laboratory determination.     

Pathways and rate coefficients for the decomposition of vinoxy and acetyl radicals

The potential in the vicinity of the stationary points on the surface for the decomposition of ground-state vinoxy and acetyl radicals has been calculated using the RQCISD(T) method extrapolated to the infinite-basis set limit. Rate coefficients for the decomposition pathways of these two radicals were computed using the master equation and variational transition state theory. Agreement between our calculated rate coefficients for H + CH(2)CO <--> CH(3) + CO and experimental data is very good, without the need for empirical adjustments to the ab initio energy barriers. Multireference configuration-interaction calculations indicate two competitive channels for vinoxy decomposition, with the channel leading to H + CH(2)CO being preferred at photodissociation energies. However, at typical combustion conditions, vinoxy decomposes primarily to CO and methyl. In contrast, decomposition of acetyl shows only one decomposition channel, leading to CO and methyl. The implications of a low-lying exit channel for the calculation of theoretical rate coefficients are discussed briefly.     

H2 + CN(n=0,1)→H + HCN振动选态反应

用从头算方法获得了Ｈ２＋ＣＮ反应的内禀反应坐标（ＩＲＣ），沿着ＩＲＣ，计算了各垂直于ＩＲＣ的简正模所对应的频率（Ｗ）以及沿ＩＲＣ运动与垂直ＩＲＣ运动的简正模之间的耦合常数（ＢＫＦ），根据传统过渡态，变分过渡态理论和选态公式，计算了ｎＣＮ＝０及ｎＣＮ＝１时反应的速率常数，并得到了实验相一致的结果，还计算了ｎＣＨ＝１及ｎＣＮ＝１的Ｈ＋ＨＣＮ→Ｈ２＋ＣＮ反应速率常数，可供实验工作者参考。     

Combined experimental and master equation investigation of the multiwell reaction H + SO2

The temperature and pressure dependence of the rate coefficient for the reaction H + SO2 has been measured using a laser flash photolysis/laser-induced fluorescence technique, for 295 10(3) atm, the latter proceeds directly from H + SO2, via the energized states of HOSO. The derived rate coefficients rely heavily on measurements of the reverse reaction, OH + SO, which has only been determined at temperatures up to 700 K.