Polymerization in the Gas Phase, in Clusters, and on Nanoparticle Surfaces

El‐Shall, M. Samy

doi:10.1021/ar7001396

Cited by 24 publications

(26 citation statements)

References 71 publications

(262 reference statements)

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“…Since in the experiment by Bernstein et al (1995) the ice was irradiated by VUV photons at the Lyman alpha wavelength, and we now know that methanimine can be efficiently ionized by those photons, we can also argue that ionization of several methanimine molecules can instead trigger the process in cold interstellar ices. This statement is in line with what is known for gas-phase polymerization of olefin (El-Shall 2008;Cottin et al 2001). Alternatively, external strong energy sources that can induce local nonequilibrium conditions, could promote neutralneutral dimerization.…”

Section: Conclusion and Implication For The Atmospheric Models Of Titsupporting

confidence: 88%

Dimerization of methanimine and its charged species in the atmosphere of Titan and interstellar/cometary ice analogs

Skouteris

Balucani

Falcinelli

et al. 2015

A&A

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Aims. We theoretically investigated the dimerization of methanimine, CH 2 =NH, a process that has been invoked to explain the formation of haze in the atmosphere of Titan and nitrogen organic compounds in interstellar/cometary ice analogs. Methods. We used density functional theory to characterize the minima and transition states of the investigated processes, while we computed the energetics with the more accurate coupled cluster method. We then obtained rate coefficients via combination of capture theory and statistical calculations. Results. The process involving two neutral molecules is characterized by significant energy barriers and cannot occur under the low temperature conditions of Titan or interstellar/cometary ices unless an external energy source is provided. On the contrary, the processes involving one molecule of either ionized or protonated methanimine are barrierless reactions and can therefore contribute to the formation of larger ions. In particular, the reaction involving ionized methanimine can also be efficient in the very low temperature conditions of the interstellar medium, leading to products of general formula C 2 N 2 H + .Conclusions. The present work suggests that polymerization of methanimine is not an efficient process in space unless an ionization/protonation or a significant energy source is available.

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Section: Conclusion and Implication For The Atmospheric Models Of Titsupporting

confidence: 88%

Dimerization of methanimine and its charged species in the atmosphere of Titan and interstellar/cometary ice analogs

Skouteris

Balucani

Falcinelli

et al. 2015

A&A

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“…Doubly charged intermediates could also explain previous observations of dehydrogenated cluster ions, and they may play a role in molecular synthesis in interstellar clouds and solar nebula where gas-phase reactions and surface catalysis on dust nanoparticles represent the major pathways. [26] Experimental Section…”

Section: +mentioning

confidence: 99%

Ion–Molecule Reactions in Helium Nanodroplets Doped with C₆₀ and Water Clusters

et al. 2009

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“…Repetition of these two basic steps can lead to larger PAHs. Recently, ion polymerization from clusters has also been suggested as a pathway for PAH generation (14,15). Several studies have focused on the formation of naphthalene, suggesting it forms via reaction of the phenyl radical with vinylacetylene (16).…”

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confidence: 99%

Ab initio dynamics and photoionization mass spectrometry reveal ion–molecule pathways from ionized acetylene clusters to benzene cation

Stein

Bandyopadhyay

Troy

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The growth mechanism of hydrocarbons in ionizing environments, such as the interstellar medium (ISM), and some combustion conditions remains incompletely understood. Ab initio molecular dynamics (AIMD) simulations and molecular beam vacuum-UV (VUV) photoionization mass spectrometry experiments were performed to understand the ion-molecule growth mechanism of small acetylene clusters (up to hexamers). A dramatic dependence of product distribution on the ionization conditions is demonstrated experimentally and understood from simulations. The products change from reactive fragmentation products in a higher temperature, higher density gas regime toward a very cold collision-free cluster regime that is dominated by products whose empirical formula is (C 2 H 2 ) n + , just like ionized acetylene clusters. The fragmentation products result from reactive ionmolecule collisions in a comparatively higher pressure and temperature regime followed by unimolecular decomposition. The isolated ionized clusters display rich dynamics that contain bonded C 4 H 4 + and C 6 H 6 + structures solvated with one or more neutral acetylene molecules. Such species contain large amounts (>2 eV) of excess internal energy. The role of the solvent acetylene molecules is to affect the barrier crossing dynamics in the potential energy surface (PES) between (C 2 H 2 ) n + isomers and provide evaporative cooling to dissipate the excess internal energy and stabilize products including the aromatic ring of the benzene cation. Formation of the benzene cation is demonstrated in AIMD simulations of acetylene clusters with n > 3, as well as other metastable C 6 H 6 + isomers. These results suggest a path for aromatic ring formation in cold acetylene-rich environments such as parts of the ISM.ion-molecule reactions | polycyclic aromatic hydrocarbons | molecular dynamics | quantum chemistry | photoionization mass spectrometry

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Polymerization in the Gas Phase, in Clusters, and on Nanoparticle Surfaces

Cited by 24 publications

References 71 publications

Dimerization of methanimine and its charged species in the atmosphere of Titan and interstellar/cometary ice analogs

Dimerization of methanimine and its charged species in the atmosphere of Titan and interstellar/cometary ice analogs

Ion–Molecule Reactions in Helium Nanodroplets Doped with C₆₀ and Water Clusters

Ab initio dynamics and photoionization mass spectrometry reveal ion–molecule pathways from ionized acetylene clusters to benzene cation

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Polymerization in the Gas Phase, in Clusters, and on Nanoparticle Surfaces

Cited by 24 publications

References 71 publications

Dimerization of methanimine and its charged species in the atmosphere of Titan and interstellar/cometary ice analogs

Dimerization of methanimine and its charged species in the atmosphere of Titan and interstellar/cometary ice analogs

Ion–Molecule Reactions in Helium Nanodroplets Doped with C60 and Water Clusters

Ab initio dynamics and photoionization mass spectrometry reveal ion–molecule pathways from ionized acetylene clusters to benzene cation

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Ion–Molecule Reactions in Helium Nanodroplets Doped with C₆₀ and Water Clusters