Bimolecular collision outcomes on multidimensional potential energy surfaces: infrared spectroscopy and activation of NO–alkane collision complexes

IF 3.4 3区 化学 Q2 Chemistry
John P. Davis, P. Garrett Burroughs, W. Churchill Wilkinson, Ellora Majumdar and Nathanael M. Kidwell
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引用次数: 0

Abstract

In bimolecular collisions between open-shell radicals and increasingly-larger alkanes, the relative impact configurations open the possibility of reactive and nonreactive outcomes that are isomer specific. To model the interaction potential between molecular scattering partners, observables are needed from experiments that can quantify both the initial molecular orientations and internal energies on multidimensional potential energy surfaces. Recent work by our group demonstrated that upon infrared (IR) excitation, the dynamics of the nitric oxide–methane collision complex (NO–CH4) are dependent on the initial monomer geometries, as small changes in configuration substantially affect the energies, electronic couplings, and predissociation pathways due to the Jahn–Teller effect. This study focuses on the isomer-specific scattering mechanisms between NO and ethane (C2H6), encoded in the spectroscopic and dynamical signatures of the NO–C2H6 collision complex. IR action spectroscopy with 1 + 1 resonance-enhanced multiphoton ionization of NO products was employed to characterize the fundamental CH stretch transitions of NO–C2H6, as well as to initiate the nonreactive decay mechanisms of the complex. Furthermore, velocity map imaging (VMI) was utilized to explore the dynamics prior to and following IR excitation of NO–C2H6, imprinted on the NO photoproducts. This work compares the dynamics from NO–C2H6 and NO–CH4 vibrational predissociation, in which substantial differences are observed in the energy exchange mechanisms during the evolution of the collision complexes to products.

Abstract Image

Abstract Image

多维势能面上的双分子碰撞结果:NO-烷烃碰撞复合物的红外光谱和活化。
在开壳自由基和越来越大的烷烃之间的双分子碰撞中,相对的撞击构型可能会产生反应性和非反应性的结果,而这些结果是同分异构体特有的。为了模拟分子散射伙伴之间的相互作用势,需要从实验中获得能量化多维势能面上初始分子方向和内部能量的观测数据。我们小组最近的研究表明,在红外(IR)激发下,一氧化氮-甲烷碰撞复合物(NO-CH4)的动力学依赖于初始单体的几何形状,因为构型的微小变化会在贾恩-泰勒效应的作用下极大地影响能量、电子耦合和预解离路径。本研究的重点是 NO 和乙烷(C2H6)之间的异构体特异性散射机制,这些机制体现在 NO-C2H6 碰撞复合物的光谱和动力学特征中。利用 1 + 1 共振增强多光子电离 NO 产物的红外行动光谱分析了 NO-C2H6 的基本 CH 伸展跃迁,并启动了复合物的非反应衰变机制。此外,还利用速度图成像(VMI)技术探索了 NO-C2H6 被红外激发之前和之后的动态,并在 NO 的光电产物上留下了印记。这项研究比较了 NO-C2H6 和 NO-CH4 振动预解离的动力学,其中观察到碰撞复合物向产物演化过程中能量交换机制的巨大差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Faraday Discussions
Faraday Discussions CHEMISTRY, PHYSICAL-
CiteScore
4.90
自引率
0.00%
发文量
259
审稿时长
2.8 months
期刊介绍: Discussion summary and research papers from discussion meetings that focus on rapidly developing areas of physical chemistry and its interfaces
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