硒化合物对不饱和脂肪酸过氧自由基的作用

本文用电子自旋共振谱技术研究了硒代二乙酸和硒代二丙酸对不饱和脂肪酸过氧自由基的作用。结果表明,硒化合物清除不饱和度为2和2以上的脂肪酸的过氧自由基,但促进仅含一个双键的不饱和脂肪酸的过氧自由基的生成。     

Density functional theory study of the reaction paths of reactions of CH3C(O)O2 radicals with HO2 in the gas phase

A DFT study on the reactions between CH₃C(O)O₂ and HO₂ radicals has been carried out. It is suggested that both the triplet and singlet potential surfaces involve a complex mechanism with the formation of loosely bound intermediate complexes of reactants and products. The reaction prefers to occur on the triplet surface to produce peracetic acid (CH₃C(O)O₂H) and triplet O₂ molecule. The CH₃C(O)O₂H can further convert into CH₃C(O)O and HO radicals.     

对流层大气过氧自由基实地测量的技术进展及其在化学机理研究中的应用

大气过氧自由基化学是对流层大气化学的重要组成部分,对于理解大气氧化性、光化学臭氧和二次有机气溶胶生成等核心科学问题具有重要意义。基于实地测量,准确掌握大气过氧自由基的浓度水平、进行相关化学行为分析以及实测结果模拟分析一直是大气过氧自由基化学研究的重点和难点。本文总结了大气过氧自由基实地测量的技术方法,回顾了涉及大气过氧自由基的大型实地观测实验,分析了已有观测实验中大气过氧自由基的浓度水平和差异,归纳了实地测量数据在化学机理研究中的应用,讨论了模拟分析实地测量结果中的主要科学发现。最后,提出该领域中尚存在的问题及可能的重点研究方向。     

ESR studies in γ‐irradiated and PS‐radiation‐grafted poly(vinylidene fluoride)

The fluoropolymer poly(vinylidene fluoride) was irradiated with γ rays to induce a polystyrene (PS) radiation grafting via an indirect method. Electron spin resonance and Fourier transform infrared studies were performed to identify the species that initiated the PS grafting. Specific experiments were performed to prove separately the importance of each kind of radical. A localization of the radicals in this irradiated polymer is proposed, and a kinetic model of the grafting is given. © 2001 John Wiley & Sons, Inc. J Polym Sci B Part B: Polym Phys 39: 1437–1448, 2001     

Mechanistic study of the reaction of methyl peroxy radical (CH3O2) with formaldehyde (CH2O)

ABSTRACT

A direct dynamic study on the reactions of CH₃O₂?+?CH₂O was carried out over the temperature range of 300–1500?K. All stationary points were calculated with the M06-2X/6-311++G(d,p) level of theory and identified for local minimum. The energetic parameters were refined at QCISD (T)/cc-pVTZ and CCSD (T)/cc-pVTZ levels of theory. Three channels were explored and a reaction of hydrogen abstraction from CH₂O by CH₃O₂ was identified as dominant channel which involves the formation of a prereactive complex in the entrance channel. The rate coefficient of the dominant channel was calculated with TST and TST/Eck and the Eckart tunnelling effect is only important over the lower temperature region. The calculated rate coefficient of the dominant channel has positive temperature dependence and agrees reasonably with the available literature data.     

Role of Hydrogen Migrations in Carbonyl Peroxy Radicals in the Atmosphere

Carbonyl peroxy radicals (RC(O)O₂) are the ubiquitous radical intermediates in the atmospheric oxidation of volatile organic compounds. In this work, theoretical studies are carried out to explore the role of the unimolecular H-migration in the carbonyl peroxy radicals by using quantum chemistry and kinetics calculations. The results showed that H-migration could be significant in the atmosphere at least in CH₃CH₂CH₂C(O)O₂ and (CH₃)₂CHCH₂C(O)O₂ with rates of ∽0.012 and ∽0.58 s^?1 at 298 K. Subsequent reactions of CH₃CHCH₂C(O)OOH would lead to the products with multi-functional groups, which might affect the aerosol formation process; while (CH₃)₂CCH₂C(O)OOH would transform to formaldehyde and acetone in a few steps. These processes would be important for the atmospheric modelling of volatileorganic compounds under low-NO_x conditions.     

Water effect on peroxy radical measurement by chemical amplification: Experimental determination and chemical mechanism

The water effect on peroxy radical measurement by chemical amplification was determined experimentally for HO2 and HO2 OH, respectively at room temperature (298±2) K and atmospheric pressure (1×105 Pa). No significant difference in water effect was observed with the type of radicals. A theoretical study of the reaction of HO2·H2O adduct with NO was performed using density functional theory at CCSD(T)/6-311 G(2d, 2p)//B3LYP/6-311 G(2d, 2p) level of theory. It was found that the primary reaction channel for the reaction is HO2·H2O NO→HNO3 H2O (R4a). On the basis of the theoretical study, the rate constant for (R4a) was calculated using Polyrate Version 8.02 program. The fitted Arrenhnius equation for (R4a) is k = 5.49×107 T 1.03exp(?14798/T) between 200 and 2000 K. A chemical model incorporated with (R4a) was used to simulate the water effect. The water effect curve obtained by the model is in accordance with that of the experiment, suggesting that the water effect is probably caused mainly by (R4a).     

Intramolecular chain reaction of artemisinin oxidation

The intramolecular chain oxidation of artemisinin was analyzed using the parabolic model. The competition of the mono- and bimolecular peroxy radicals formed from artemisinin was considered. Artemisinin is predominantly oxidized via the intramolecular chain mechanism to form polyatomic hydroperoxides. This results in the situation when, under aerobic conditions, artemisinin is transformed from the monofunctional into polyfunctional initiator with several hydroperoxide groups. The enthalpy was calculated, and the activation energies and rate constants of the intramolecular reactions of the artemisinin peroxy radicals, as well as those of their bimolecular reactions with C-H, S-H, and O-H bonds of biological substrates and their analogs, were calculated in the framework of the parabolic model. A new kinetic scheme for artemisinin oxidation was proposed. Published in Russian in Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 2, pp. 267–275, February, 2008.