Quantitative determination of the selectivities of five different phenyl radicals in hydrogen atom abstraction from ethanol

Jing, Linhong; Guler, Leonard P.; Nash, John J.; Kenttämaa, Hilkka I.

doi:10.1016/j.jasms.2004.02.009

Cited by 16 publications

(34 citation statements)

References 24 publications

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“…Previous studies of positively charged phenyl radicals in the gas phase have shown that the selectivity of hydrogen atom abstraction from ethanol is related to the EAs of the radicals. 47 Radicals with a lower EA (indicating lower reactivity) tend to attack the CH 2 -group rather than the CH 3 -group of ethanol because the CH 2 -group has a lower homolytic C-H bond dissociation energy. Indeed, in the gas phase, the hydrogen atom abstraction efficiency from methanol is 1.7 % and 0.4 % for the protonated 3- and 4-isomers, respectively.…”

Section: Resultsmentioning

confidence: 99%

Direct Comparison of Solution and Gas-Phase Reactions of the Three Distonic Isomers of the Pyridine Radical Cation with Methanol

et al. 2012

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In order to directly compare the reactivity of positively charged carbon-centered aromatic σ-radicals toward methanol in solution and in the gas phase, the 2-, 3-, and 4-dehydropyridinium cations (distonic isomers of the pyridine radical cation) were generated by ultraviolet photolysis of the corresponding iodo-precursors in a mixture of water and methanol at varying pH. The reaction mixtures were analyzed by using liquid chromatography/mass spectrometry. Hydrogen atom abstraction was the only reaction observed for the 3- and 4-dehydropyridinium cations (and –pyridines) in solution. This also was the major reaction observed earlier in the gas phase. Depending on the pH, the hydrogen atom can be abstracted from different molecules (i.e., methanol or water) and from different sites (in methanol) by the 3- and 4-dehydropyridinium cations/-pyridines in solution. In the pH range of 1 – 4, the methyl group of methanol is the main hydrogen atom donor site for both 3- and 4-dehydropyridinium cations (just like in the gas phase). At higher pH, the hydroxyl groups of water and methanol also act as hydrogen atom donors. This finding is rationalized by a greater abundance of the unprotonated radicals that preferentially abstract hydrogen atoms from the polar hydroxyl groups. The percentage yield of hydrogen atom abstraction by these radicals was found to increase with lowering the pH in the pH range of 1.0-3.2. This pH effect is rationalized by polar effects: the lower the pH, the greater the fraction of protonated (more polar) radicals in the solution. This finding is consistent with previous results obtained in the gas phase and suggests that gas-phase studies can be used to predict solution reactivity, but only as long as the same reactive species is studied in both experiments. This was found not to be the case for the 2-iodopyridinium cation. Photolysis of this precursor in solution resulted in the formation of two major addition products, 2-hydroxy- and 2-methoxypyridinium cations, in addition to the hydrogen atom abstraction product. These addition products were not observed in the earlier gas-phase studies on 2-dehydropyridinium cation. Their observation in solution is explained by the formation of another reactive intermediate, the 2-pyridyl cation, upon photolysis of 2-iodopyridinium cation (and 2-iodopyridine). The same intermediate was observed in the gas phase but it was removed before examining the reactions of the desired radical, 2-dehydropyridinium cation (which cannot be done in solution).

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Section: Resultsmentioning

confidence: 99%

Direct Comparison of Solution and Gas-Phase Reactions of the Three Distonic Isomers of the Pyridine Radical Cation with Methanol

et al. 2012

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“…Because the ionic avoided curve crossing model (described above) predicts that the reaction efficiencies should also depend on the difference between the IE of the hydrogen-atom donor and the EA of the aryl radical (i.e., (IE – EA)), it was of interest to examine this relationship by using several different aryl radicals and hydrogen-atom donors. Thus, reaction efficiencies (measured here for cyclohexane and isopropanol, or measured previously) for hydrogenatom abstraction from ethanol by seven different aryl radicals ( g , k , l , n , q , s , t ),61,76 from tetrahydrofuran by twenty different aryl radicals ( b , c , d , e , f , g , h , i , j , l , m , q , s , t , aa , bb , cc , dd , ee , ff ),22,23,27,28,63 and from 2-methyltetrahydrofuran by eleven different aryl radicals ( b , d , e , f , h , i , j , m , s , aa , bb ),23 were studied. The calculated (IE – EA) values and the reaction efficiencies for hydrogen-atom abstraction are listed in Table 5.…”

Section: Resultsmentioning

confidence: 99%

Correlation of Hydrogen-Atom Abstraction Reaction Efficiencies for Aryl Radicals with their Vertical Electron Affinities and the Vertical Ionization Energies of the Hydrogen-Atom Donors

2008

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The factors that control the reactivities of aryl radicals toward hydrogen-atom donors were studied by using a dual-cell Fourier-transform ion cyclotron resonance mass spectrometer (FT – ICR). Hydrogen-atom abstraction reaction efficiencies for two substrates, cyclohexane and isopropanol, were measured for twenty-three structurally different, positively-charged aryl radicals, which included dehydrobenzenes, dehydronaphthalenes, dehydropyridines, and dehydro(iso)quinolines. A logarithmic correlation was found between the hydrogen-atom abstraction reaction efficiencies and the (calculated) vertical electron affinities (EA) of the aryl radicals. Transition state energies calculated for three of the aryl radicals with isopropanol were found to correlate linearly with their (calculated) EAs. No correlation was found between the hydrogen-atom abstraction reaction efficiencies and the (calculated) enthalpy changes for the reactions. Measurement of the reaction efficiencies for the reactions of several different hydrogen-atom donors with a few selected aryl radicals revealed a logarithmic correlation between the hydrogen-atom abstraction reaction efficiencies and the vertical ionization energies (IE) of the hydrogen-atom donors, but not the lowest homolytic X – H (X = heavy atom) bond dissociation energies of the hydrogen-atom donors. Examination of the hydrogen-atom abstraction reactions of twenty-nine different aryl radicals and eighteen different hydrogen-atom donors showed that the reaction efficiency increases (logarithmically) as the difference between the IE of the hydrogen-atom donor and the EA of the aryl radical decreases. This dependence is likely to result from the increasing polarization, and concomitant stabilization, of the transition state as the energy difference between the neutral and ionic reactants decreases. Thus, the hydrogen-atom abstraction reaction efficiency for an aryl radical can be “tuned” by structural changes that influence either the vertical EA of the aryl radical or the vertical IE of the hydrogen atom donor.

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“…However, the calculated reaction enthalpies (ΔH rxn ) associated with the hydrogen atom abstraction reactions of charged radicals 2 – 4 with methanol and ethanol (Table 3) do not reflect the observed differences in the reaction rates with these two neutral reagents. For example, ΔH rxn for hydrogen atom abstraction from the α-carbon in ethanol48 by 2 is only 0.2 and 3.3 kcal/mol more exothermic than those for 3 and 4 (ΔH rxn ; −25.6, −25.4 and −22.3 kcal/mol, respectively; Table 3), yet the reaction efficiency for hydrogen atom abstraction by 2 (33%; Table 1) differs from that of 3 (11%) by a factor of three and from that of 4 (4.2%) by a factor of about eight. Similar trends are also observed for methanol (Tables 1 and 3).…”

Section: Discussionmentioning

confidence: 99%

Gas-Phase Reactivity of Protonated 2-, 3-, and 4-Dehydropyridine Radicals Toward Organic Reagents

et al. 2009

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In order to explore the effects of the electronic nature of charged phenyl radicals on their reactivity, reactions of the three distonic isomers of ndehydropyridinium cation (n = 2, 3 or 4) have been investigated in the gas phase by using Fourier-transform ion cyclotron resonance mass spectrometry. All three isomers react with cyclohexane, methanol, ethanol and 1-pentanol exclusively via hydrogen atom abstraction, and with allyl iodide mainly via iodine atom abstraction, with a reaction efficiency ordering: 2 > 3 > 4. The observed reactivity ordering correlates well with the calculated vertical electron affinities of the charged radicals (i.e., the higher the vertical electron affinity, the faster the reaction). Charged radicals 2 and 3 also react with tetrahydrofuran exclusively via hydrogen atom abstraction, but the reaction of 4 with tetrahydrofuran yields products arising from nonradical reactivity. The unusual reactivity of 4 is likely to result from the contribution of an ionized carbenetype resonance structure that facilitates nucleophilic addition to the most electrophilic carbon atom (C-4) in this charged radical. The influence of such a resonance structure on the reactivity of 2 is not obvious, and this may be due to stabilizing hydrogen-bonding interactions in the transition states for this molecule. Charged radicals 2 and 3 abstract a hydrogen atom from the substituent in both phenol and toluene, but 4 abstracts a hydrogen atom from the phenyl ring -a reaction that is unprecedented for phenyl radicals. Charged radical 4 reacts with tert-butyl isocyanide mainly by hydrogen cyanide (HCN) abstraction while CN abstraction is the principal reaction for 2 and 3. The different reactivity observed for 4 (compared to 2 and 3) is likely to result from different charge and spin distributions of the reaction intermediates for these charged radicals.

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Quantitative determination of the selectivities of five different phenyl radicals in hydrogen atom abstraction from ethanol

Cited by 16 publications

References 24 publications

Direct Comparison of Solution and Gas-Phase Reactions of the Three Distonic Isomers of the Pyridine Radical Cation with Methanol

Direct Comparison of Solution and Gas-Phase Reactions of the Three Distonic Isomers of the Pyridine Radical Cation with Methanol

Correlation of Hydrogen-Atom Abstraction Reaction Efficiencies for Aryl Radicals with their Vertical Electron Affinities and the Vertical Ionization Energies of the Hydrogen-Atom Donors

Gas-Phase Reactivity of Protonated 2-, 3-, and 4-Dehydropyridine Radicals Toward Organic Reagents

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