甲基环己烷在9∽15.5 eV能量区的真空紫外光电离研究

利用具有同步辐射源的反射式飞行时间质谱仪，研究甲基环己烷的真空紫外光电离和光解离. 观测到母体离子C₇H₁₄⁺和碎片离子C₇H₁₃⁺，C₆H₁₁⁺，C₆H₁₀⁺，C₅H₁₀⁺，C₅H₉⁺，C₄H₈⁺，C₄H₇⁺和C₃H₅⁺的光电离效率曲线. 测定甲基环己烷的电离能为9.80±0.03 eV，通过光电离效率曲线确定其碎片离子的出现势. 在B3LYP/6-31G(d)水平上对过渡态、中间体和产物离子的优化结构进行表征，并使用G3B3方法计算其能量. 提出主要碎片离子的形成通道. 分子内氢迁移和碳开环是甲基环己烷裂解途径中最重要的过程.     

发射光谱法研究甲基环己烷燃烧时激发态自由基时间历程

采用三组单色仪探测系统,测量了甲基环己烷在高温反射激波作用下瞬态燃烧反应过程中三种激发态自由基OH*,CH*和C*₂的特征光辐射,得到了激发态自由基时间历程和光辐射相对强度随温度的变化规律。反射激波温度1 200～1 700 K,激波压力1.5 atm,甲基环己烷摩尔分数0.1%,当量比1.0。在点火燃烧初始阶段三种自由基几乎同时产生,自由基持续时间随着温度的升高而变短。相同温度下CH*和OH*自由基持续时间大于C*₂自由基,在1 400 K以下C*₂自由基发光消失。OH*和CH*自由基发光强度在T<1 400 K时对温度变化不敏感,而在T>1 400 K时CH*自由基峰值随温度快速增长,C*₂和OH*峰值随温度增大比较平缓。将实验结果和化学反应机理模拟结果进行了对比,实验获得的OH*自由基时间历程在低温时和机理预测结果吻合较好,但在高温时有一定差异。CH*自由基时间历程在高温与机理结果吻合较好,在低温时机理预测结果CH*自由基持续时间要长于实验结果。实验测得的结果为含激发态物种化学反应动力学机理的验证和优化提供了依据。     

Excess molar enthalpies of binary mixtures of 1-hexene with some cyclic and aromatic hydrocarbons at 298.15 K

Microcalorimetric measurements of excess molar enthalpies, at 298.15 K, are reported for the four binary systems formed by mixing 1-hexene with the cycloalkanes: cyclohexane and methylcyclohexane, and with the aromatic hydrocarcons: benzene and toluene. Smooth Redlich-Kister representations of the results are presented. It was found that the Liebermann-Fried model also provided good representations of the results.     

Excess Molar Volumes,Viscosities and Speeds of Sound of the Ternary Mixture 1-Heptanol (1) + Tetrachloroethylene (2) + Methylcyclohexane (3) at 298.15 K

Densities (ρ), viscosities (η) and speeds of sound (u) of the ternary mixture (1-heptanol + tetrachloroethylene + methylcyclohexane) and the corresponding binary mixtures (1-heptanol + tetrachloroethylene), (1-heptanol + methylcyclohexane) and (tetrachloroethylene + methylcyclohexane) at 298.15 K were measured over the whole composition range. The data obtained are used to calculate the excess molar volumes (V ^E), excess isobaric thermal expansivities (α ^E), viscosity deviations (Δη), excess Gibbs energies of activation of viscous flow (ΔG ^*E) and excess isentropic compressibilities (κ _S ^E) of the binary and ternary mixtures. The data from the binary systems were fitted by the Redlich–Kister equation whereas the best correlation method for the ternary system was found using the Nagata equation. Viscosities, speeds of sound and isentropic compressibilities of the binary and ternary mixtures have been correlated by means of several empirical and semi-empirical equations. The best correlation method for viscosities of binary systems is found using the Iulan et al. equation and for the ternary system using the Heric and McAllister equations. The best correlation method for the speeds of sound and isentropic compressibilities of the binary system (1-heptanol + methylcyclohexane) is found using IMR (Van Deal ideal mixing relation) and for the binary system (tetrachloroethylene + methylcyclohexane) it is found using the NR (Nomoto relation) and for the binary system (1-heptanol + tetrachloroethylene) and the ternary system (1-heptanol + trichloroethylene + methylcyclohexane) it is obtained from the FLT (Jacobson free length theory).     

甲基环己烷燃烧反应特性的光谱研究

利用激波管实验装置由反射激波点火,在点火温度1 164～1 566 K,点火压力1.03～1.99 atm,燃料浓度为1.0%,当量比为1.0的条件下,用光谱单色仪、光电倍增管、压力传感器和示波器等组成测试系统,测量了甲基环己烷燃烧过程中主要中间产物OH,CH和C2自由基特征光辐射随时间的连续变化,并测得了甲基环己烷/氧气/氩气的点火延迟时间。通过对测量结果的分析,初步认识了甲基环己烷燃烧反应中几个主要中间产物的光辐射特性及其反映出的甲基环己烷燃烧反应特性。实验所测点火延迟时间与已报道的实验结果和燃烧反应机理预测结果符合较好。本文实验结果为构建和验证甲基环己烷燃烧反应机理提供了实验依据。     

Modeling and experimental investigation of methylcyclohexane ignition in a rapid compression machine

A new chemical kinetic reaction mechanism has been developed for the oxidation of methylcyclohexane (MCH), combining a new low temperature mechanism with a recently developed high temperature mechanism. Predictions from this kinetic model are compared with new experimentally measured ignition delay times from a rapid compression machine. Computed results were found to be particularly sensitive to isomerization rates of methylcyclohexylperoxy radicals. Three different methods were used to estimate rate constants for these isomerization reactions. Rate constants based on comparable alkylperoxy radical isomerizations corrected for the differences in the structure of MCH and the respective alkane, predicted ignition delay times in very poor agreement with the experimental results. The most significant drawback was the complete absence of a region of negative temperature coefficient (NTC) in the model results using this method, although a prominent NTC region was observed experimentally. Alternative estimates of the isomerization reaction rate constants, based on the results from previous experimental studies of low temperature cyclohexane oxidation, provided much better agreement with the present experiments, including the pronounced NTC behavior. The most important feature of the resulting methylcyclohexylperoxy radical isomerization reaction analysis was found to be the relative rates of isomerizations that proceed through 5-, 6-, and 7-membered transition state ring structures and their different impacts on the chain branching behavior of the overall mechanism. Theoretical implications of these results are discussed, with particular attention paid to how intramolecular H atom transfer reactions are influenced by the differences between linear alkane and cycloalkane structures.     

Experimental study of cyclohexane and methylcyclohexane oxidation at low to intermediate temperature in a motored engine

This work concerns the oxidation of cyclohexane and methylcyclohexane in a motored engine at low to intermediate temperatures, which is largely unknown in the literature. The experiment is conducted with variable compression ratio from 4 to 15 at equivalence ratio 0.25 and intake temperatures of 120 °C and 200 °C. Results show that overall reaction activity, indicated by fuel conversion and carbon monoxide formation, is largely enhanced by the existence of the methyl group. Cyclohexane shows a stronger negative temperature coefficient (NTC) behavior than methylcyclohexane. Detailed product analyses reveal that conjugated olefins are the major product for cyclohexane and methylcyclohexane in both low temperature oxidation and NTC regime. Four C₆ oxygenates, 5-hexen-1-al, 1,2-epoxycyclohexane, 1,4-epoxycyclohexane, and cyclohexanone are detected in cyclohexane oxidation. The relative yields indicate that intramolecular hydrogen abstraction of cyclohexylperoxy radical is more likely to occur on γ-carbons than on α-, β-, or δ-carbons. Four conjugated olefins, 1-, 3-, 4-methylcyclohexenes and methylenecyclohexane, are detected in methylcyclohexane oxidation, with relative yield about 1, 1.2, 1.4 and 0.25, respectively.     

Competitive conversion of methylcyclohexane andn-octane. Variation of hydrogen partial pressure

The presence of added hydrogen does not significantly alter the relative conversion of methylcyclohexane andn-octane. The results for conversion at a total pressure of 0.1 mPa are consistent with a mechanism where chemisorption is irreversible and rate limiting even where the hydrogen partial pressure is 0.094 mPa. Dedicated to Professor Pál Tétényi on the occasion of his 70th birthday