卤代烃可能消耗大气臭氧

IF 2.1 4区 化学 Q3 CHEMISTRY, PHYSICAL
A. Mamantov
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引用次数: 1

摘要

在模拟对流层烟雾室研究中,四氯乙烯(PERC)和三氯乙烯(TCE)的光氧化发生有一定的时间延迟,加速了O3/氯化乙烯(CE)浓度的同时降低以及CCl2O的增加,这在PERC和CCl2的情况下归因于CCl2,而在TCE中归因于CHCl。羰基、氯化乙酰氯化物和CCl2O的产物可由氧化和/或激发氧化CE的重排产生,例如环氧化物。分析表明,清除实验并没有证明氯原子的存在是氯化乙酰氯形成的原因。卤代烃可以与O3形成配合物,并通过电子转移(ET)使O3解离为O2和O,使卤代烃再生,形成链式反应。ET的方向可以由二氧化碳和O3之间最小的HOMO-LUMO能量差决定,这导致了更大的过渡态稳定性。讨论了O3与碳烯和简单烯烃、亲核碳烯与缺电子烯烃、亲电碳烯PhCCl与烷基取代烯烃反应的相似之处,即(1)形成络合物、(2)极低或负活化能和(3)与烷基烯烃发生ET反应的能力。分析了世界范围内使用的全氟化碳、氢全氟化碳、其卤化替代品和起始材料降解为可降解O3的卤代烃的可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Halocarbenes May Deplete Atmospheric Ozone
Photooxidation of tetrachloroethylene (PERC) and trichloroethylene (TCE) in simulated tropospheric smog chamber studies occurs with a time delay, accelerating simultaneous decreasing O3/chlorinated ethylene (CE) concentrations along with increasing CCl2O, which is attributed to CCl2 in the case of PERC and CCl2 or CHCl for TCE. The carbenes, chlorinated acetyl chlorides and CCl2O products may result from the rearrangement of the oxidised and/or excited oxidised CE, e.g. an epoxide. Analyses indicate scavenging experiments have not proved the existence of Cl atoms as being responsible for chlorinated acetyl chloride formation. Halocarbenes may form complexes with O3 which can undergo electron transfer (ET) and lead to dissociation of O3 to O2 and O and regeneration of carbene, resulting in a chain reaction. The direction of ET may be determined by the smallest differential HOMO–LUMO energy between the carbene and O3 which results in greater transition state stabilisation. Similarities in the reactions of O3 with carbenes and simple alkenes, nucleophilic carbenes with electron-poor alkenes and electrophilic carbene PhCCl with alkyl-substituted alkenes, i.e. (1) complex formation, (2) very low or negative activation energies and (3) the ability to undergo ET reactions with alkylalkenes are discussed. The possibility of the world-wide used perhalocarbons, e.g. perfluorinated carbons, hydroperhalocarbons, their halogenated replacements and starting materials degrading to halocarbenes which may degrade O3, is analysed.
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来源期刊
CiteScore
2.10
自引率
0.00%
发文量
5
审稿时长
2.3 months
期刊介绍: The journal covers the fields of kinetics and mechanisms of chemical processes in the gas phase and solution of both simple and complex systems.
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