Scheer Adam M, Eskola Arkke J, Osborn David L, Sheps Leonid, Taatjes Craig A
Combustion Research Facility, Sandia National Laboratories , MS 9055, Livermore, California 94551, United States.
J Phys Chem A. 2016 Nov 3;120(43):8625-8636. doi: 10.1021/acs.jpca.6b07370. Epub 2016 Oct 25.
The pulsed photolytic chlorine-initiated oxidation of diethyl ketone [DEK; (CHCH)C═O], 2,2,4,4-d-DEK [d-DEK; (CHCD)C═O], and 1,1,1,5,5,5-d-DEK [d-DEK; (CDCH)C═O] is studied at 8 torr and 1-2 atm and from 400-625 K. Cl atoms produced by laser photolysis react with diethyl ketone to form either primary (3-pentan-on-1-yl, R) or secondary (3-pentan-on-2-yl, R) radicals, which in turn react with O. Multiplexed time-of-flight mass spectrometry, coupled to either a hydrogen discharge lamp or tunable synchrotron photoionizing radiation, is used to detect products as a function of mass, time, and photon energy. At 8 torr, the nature of the chain propagating cyclic ether + OH channel changes as a function of temperature. At 450 K, the production of OH is mainly in conjunction with formation of 2,4-dimethyloxetan-3-one, resulting from reaction of the resonance-stabilized secondary R with O. In contrast, at 550 K and 8 torr, 2-methyl-tetrahydrofuran-3-one, originating from oxidation of the primary radical (R), is observed as the dominant cyclic ether product. Formation of both of these cyclic ether production channels proceeds via a resonance-stabilized hydroperoxy alkyl (QOOH) intermediate. Little or no ketohydroperoxide (KHP) is observed under the low-pressure conditions. At higher O concentrations and higher pressures (1-2 atm), a strong KHP signal appears as the temperature is increased above 450 K. Definitive isomeric identification from measurements on the deuterated DEK isotopologues indicates the favored pathway produces a γ-KHP via resonance-stabilized alkyl, QOOH, and HOOPOOH radicals. Time-resolved measurements reveal the KHP formation becomes faster and signal more intense upon increasing temperature from 450 to 575 K before intensity drops significantly at 625 K. The KHP time profile also shows a peak followed by a gradual depletion for the extent of experiment. Several tertiary products exhibit a slow accumulation in coincidence with the observed KHP decay. These products can be associated with decomposition of KHP by β-scission pathways or via isomerization of a γ-KHP into a cyclic peroxide intermediate (Korcek mechanism). The oxidation of d-DEK, where kinetic isotope effects disfavor γ-KHP formation, shows greatly reduced KHP formation and associated signatures from KHP decomposition products.
在8托和1 - 2个大气压以及400 - 625K的条件下,研究了脉冲光解氯引发的二乙酮[DEK;(CHCH)C═O]、2,2,4,4 - d - DEK [d - DEK;(CHCD)C═O]和1,1,1,5,5,5 - d - DEK [d - DEK;(CDCH)C═O]的氧化反应。激光光解产生的氯原子与二乙酮反应形成伯(3 - 戊酮 - 1 - 基,R)或仲(3 - 戊酮 - 2 - 基,R)自由基,这些自由基进而与O反应。与氢放电灯或可调谐同步辐射光电离辐射耦合的多路飞行时间质谱仪,用于检测产物随质量、时间和光子能量的变化。在8托时,链增长的环醚 + OH通道的性质随温度而变化。在450K时,OH的产生主要与2,4 - 二甲基氧杂环丁烷 - 3 - 酮的形成相关,这是由共振稳定的仲R与O反应产生的。相比之下,在550K和8托时,观察到源自伯自由基(R)氧化的2 - 甲基 - 四氢呋喃 - 3 - 酮是主要的环醚产物。这两个环醚生成通道的形成均通过共振稳定的氢过氧烷基(QOOH)中间体进行。在低压条件下几乎观察不到或没有观察到酮氢过氧化物(KHP)。在较高的O浓度和较高压力(1 - 2个大气压)下,当温度升高到450K以上时,会出现强烈的KHP信号。对氘代DEK同位素异构体的测量进行的明确异构体鉴定表明,有利的途径是通过共振稳定的烷基、QOOH和HOOPOOH自由基生成γ - KHP。时间分辨测量表明,随着温度从450K升高到575K,KHP的形成变得更快且信号更强,然后在625K时强度显著下降。KHP的时间曲线在实验范围内也显示出一个峰值,随后逐渐耗尽。几种叔产物的积累缓慢,与观察到的KHP衰减同时发生。这些产物可能与KHP通过β - 断裂途径的分解或γ - KHP异构化为环状过氧化物中间体(科尔切克机制)有关。d - DEK的氧化反应中,动力学同位素效应不利于γ - KHP的形成,其KHP的形成以及KHP分解产物的相关特征大大降低。
