Double C--H Activation of Ethane by Metal-Free SO sub(2) super(.+) Radical Cations

The room-temperature C--H activation of ethane by metal-free SO sub(2) super(.+) radical cations has been investigated under different pressure regimes by mass spectrometric techniques. The major reaction channel is the conversion of ethane to ethylene accompanied by the formation of H sub(2)SO sub(...

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Veröffentlicht in:	Chemistry : a European journal 2010-06, Vol.16 (21), p.6234-6242
Hauptverfasser:	dePetris, Giulia, Cartoni, Antonella, Troiani, Anna, Barone, Vincenzo, Cimino, Paola, Angelini, Giancarlo, Ursini, Ornella
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Sprache:	eng
Schlagworte:	Activation Activation analysis Cations Conversion Ethane Ethylene Radicals Reaction kinetics
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creator	dePetris, Giulia Cartoni, Antonella Troiani, Anna Barone, Vincenzo Cimino, Paola Angelini, Giancarlo Ursini, Ornella
description	The room-temperature C--H activation of ethane by metal-free SO sub(2) super(.+) radical cations has been investigated under different pressure regimes by mass spectrometric techniques. The major reaction channel is the conversion of ethane to ethylene accompanied by the formation of H sub(2)SO sub(2) super(.+), the radical cation of sulfoxylic acid. The mechanism of the double C--H activation, in the absence of the single activation product HSO sub(2) super(+), is elucidated by kinetic studies and quantum chemical calculations. Under near single-collision conditions the reaction occurs with rate constant k=1.010 super(-9) ( plus or minus 30%)cm super(3)s super(-1)molecule super(-1), efficiency=90%, kinetic isotope effect k sub(H)/k sub(D)=1.1, and partial H/D scrambling. The theoretical analysis shows that the interaction of SO sub(2) super(.+) with ethane through an oxygen atom directly leads to the C--H activation intermediate. The interaction through sulfur leads to an encounter complex that rapidly converts to the same intermediate. The double C--H activation occurs by a reaction path that lies below the reactants and involves intermediates separated by very low energy barriers, which include a complex of the ethyl cation suitable to undergo H/D scrambling. Key issues in the observed reactivity are electron-transfer processes, in which a crucial role is played by geometrical constraints. The work shows how mechanistic details disclosed by the reactions of metal-free electrophiles may contribute to the current understanding of the C--H activation of ethane. Two at once: The SO sub(2) super(.+) radical cation assists an exothermic and effective conversion of ethane to ethylene by double C--H activation at room temperature. Charge and spin effects are strictly related to geometrical constraints of short-lived intermediates, like the ion-molecule complexes containing the ethyl radical and the ethyl cation, respectively (see figure).
doi_str_mv	10.1002/chem.200903588
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The major reaction channel is the conversion of ethane to ethylene accompanied by the formation of H sub(2)SO sub(2) super(.+), the radical cation of sulfoxylic acid. The mechanism of the double C--H activation, in the absence of the single activation product HSO sub(2) super(+), is elucidated by kinetic studies and quantum chemical calculations. Under near single-collision conditions the reaction occurs with rate constant k=1.010 super(-9) ( plus or minus 30%)cm super(3)s super(-1)molecule super(-1), efficiency=90%, kinetic isotope effect k sub(H)/k sub(D)=1.1, and partial H/D scrambling. The theoretical analysis shows that the interaction of SO sub(2) super(.+) with ethane through an oxygen atom directly leads to the C--H activation intermediate. The interaction through sulfur leads to an encounter complex that rapidly converts to the same intermediate. The double C--H activation occurs by a reaction path that lies below the reactants and involves intermediates separated by very low energy barriers, which include a complex of the ethyl cation suitable to undergo H/D scrambling. Key issues in the observed reactivity are electron-transfer processes, in which a crucial role is played by geometrical constraints. The work shows how mechanistic details disclosed by the reactions of metal-free electrophiles may contribute to the current understanding of the C--H activation of ethane. Two at once: The SO sub(2) super(.+) radical cation assists an exothermic and effective conversion of ethane to ethylene by double C--H activation at room temperature. Charge and spin effects are strictly related to geometrical constraints of short-lived intermediates, like the ion-molecule complexes containing the ethyl radical and the ethyl cation, respectively (see figure).</description><identifier>ISSN: 0947-6539</identifier><identifier>EISSN: 1521-3765</identifier><identifier>DOI: 10.1002/chem.200903588</identifier><language>eng</language><subject>Activation ; Activation analysis ; Cations ; Conversion ; Ethane ; Ethylene ; Radicals ; Reaction kinetics</subject><ispartof>Chemistry : a European journal, 2010-06, Vol.16 (21), p.6234-6242</ispartof><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,776,780,27901,27902</link.rule.ids></links><search><creatorcontrib>dePetris, Giulia</creatorcontrib><creatorcontrib>Cartoni, Antonella</creatorcontrib><creatorcontrib>Troiani, Anna</creatorcontrib><creatorcontrib>Barone, Vincenzo</creatorcontrib><creatorcontrib>Cimino, Paola</creatorcontrib><creatorcontrib>Angelini, Giancarlo</creatorcontrib><creatorcontrib>Ursini, Ornella</creatorcontrib><title>Double C--H Activation of Ethane by Metal-Free SO sub(2) super(.+) Radical Cations</title><title>Chemistry : a European journal</title><description>The room-temperature C--H activation of ethane by metal-free SO sub(2) super(.+) radical cations has been investigated under different pressure regimes by mass spectrometric techniques. 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The double C--H activation occurs by a reaction path that lies below the reactants and involves intermediates separated by very low energy barriers, which include a complex of the ethyl cation suitable to undergo H/D scrambling. Key issues in the observed reactivity are electron-transfer processes, in which a crucial role is played by geometrical constraints. The work shows how mechanistic details disclosed by the reactions of metal-free electrophiles may contribute to the current understanding of the C--H activation of ethane. Two at once: The SO sub(2) super(.+) radical cation assists an exothermic and effective conversion of ethane to ethylene by double C--H activation at room temperature. 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source	Wiley Online Library Journals Frontfile Complete
subjects	Activation Activation analysis Cations Conversion Ethane Ethylene Radicals Reaction kinetics
title	Double C--H Activation of Ethane by Metal-Free SO sub(2) super(.+) Radical Cations
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