Lactone-Derived Carbon-Centered Radicals:  Formation and Reactivity with Oxygen

Bejan, Elena; Font‐Sanchis, Enrique; Scaiano, J. C.

doi:10.1021/ol0167917

Cited by 81 publications

(82 citation statements)

References 21 publications

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“…Using categories defined in previous work, particularly by Scaiano et al, 7,[9][10][11] we are able to make the following generalizations: (1) vinyl is a more powerful functional group than phenyl, because allyl radical distributes spin density more effectively than benzyl, where it tends to concentrate on the benzylic (exocyclic) carbon; (4) simple ortho-, meta-, and para-effects using the À ÀNO 2 group are minor, when considering stabilization of the benzyl radical; (5) lactones and to a lesser extent isolactones are important stabilizing groups, but benzolactones offer only a small improvement over lactones; (6) captodative stabilization provides a very strong radical stabilizing force, and the carbonyl acceptor seems to be special in this respect; (7) starting from cyclohexadienyl radical, spin delocalization onto a heteroatom is a useful design strategy; (8) the improvement in desired properties by using stereoelectronic effects in our examples (i.e., fluorene) is small, relative to unconstrained phenyl groups. Thus, stereoelectronic effects using the fluorenyl group are weak, although introduction of an oxygen into a six-membered ring adjacent to benzenes results in somewhat better stabilization; (9) considering all of the aforementioned effects, we have tabulated Gibbs free energies of addition for a variety of molecules, approximately half of which will be resistant to the addition of molecular oxygen.…”

Section: Discussionmentioning

confidence: 99%

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Stability of carbon‐centered radicals: Effect of functional groups on the energetics of addition of molecular oxygen

2008

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In this paper we examine a series of hydrocarbons with structural features which cause a weakening of the C-H bond. We use theoretical calculations to explore whether the carbon-centered radicals R(*) which are created after breaking the bond can be stabilized enough so that they resist the addition of molecular oxygen, i.e. where the reaction R(*) + O(2) --> ROO(*) becomes energetically unfavorable. Calculations using a B3LYP-based method provide accurate bond dissociation enthalpies (BDEs) for R-H and R-OO(*) bonds, as well as Gibbs free energy changes for the addition reaction. The data show strong correlations between R-OO(*) and R-H BDEs for a wide variety of structures. They also show an equally strong correlation between the R-OO(*) BDE and the unpaired spin density at the site of addition. Using these data we examine the major functional group categories proposed in several experimental studies, and assess their relative importance. Finally, we combine effects to try to optimize resistance to the addition of molecular oxygen, an important factor in designing carbon-based antioxidants.

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Section: Discussionmentioning

confidence: 99%

“…9 Category A consists of simple substituents surrounding a carbon radical. B has conjugative delocalizing groups and their (oxygen) heteroatom analogues.…”

Section: Structures and Categoriesmentioning

confidence: 99%

Stability of carbon‐centered radicals: Effect of functional groups on the energetics of addition of molecular oxygen

2008

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“…Thework of Cheng and co-workers supported this observation because the molar mass of polystyrene calculated from SEC decreased by freezing the solution but recovered by heating to 100 8 8C. [37][38][39] Because of these distinctive properties,t his radical system enables in situ quantitative evaluation of polymer chain scission through electron paramagnetic spectroscopic (EPR) studies,u nlike previously reported mechanophores. [31,32] These studies suggest that freezing polymer solutions does not generate polymer chain scission but conformational changes.T herefore,w hether freezing polymer solutions actually induces mechanical force along the polymer chains and if so,t he magnitude of the force generated, remains unclear.…”

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confidence: 99%

Mechanophores with a Reversible Radical System and Freezing‐Induced Mechanochemistry in Polymer Solutions and Gels

et al. 2015

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Visualization and quantitative evaluation of covalent bond scission in polymeric materials are highly important for understanding failure, fatigue, and deterioration mechanisms and improving the lifetime, durability, toughness, and reliability of the materials. The diarylbibenzofuranone-based mechanophore radical system enabled, through electron paramagnetic resonance spectroscopy, in situ quantitative evaluation of scission of the mechanophores and estimation of mechanical energy induced along polymer chains by external forces. The coagulation of polymer solutions by freezing probably generated force but did not cleave the mechanophores. On the other hand, cross-linking led to efficient propagation of the force of more than 80 kJ mol(-1) to some mechanophores, resulting their cleavage and generation of colored stable radicals. This mechanoprobe concept has the potential to elucidate other debated issues in the polymer field as well.

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“…The probe was also used to study the formation and percolation of carbon-centered radicals produced by thermolysis of the size-excluded dimer, 3,3'-diphenyl-3H,3H'-[3,3']bisbenzofuranyl-2,2'-dione (Scheme 9). The resulting 3-phenyl-2-coumaranone radicals (PC • ) are able to penetrate the zeolite pores, and the documented persistency of these radicals ensures that they will survive to migrate through the zeolite pore structure [122][123][124][125][126]. A fluorescence increase over time was observed as PC • radicals penetrate the zeolite pores, and encounter and couple with the embedded prefluorescent probe.…”

Section: Monitoring Intrazeolite Radical Reactionsmentioning

confidence: 99%

Supramolecular photochemistry in zeolites: From catalysts to sunscreens

Chrétien

2007

Pure and Applied Chemistry

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Zeolites are nanoporous, crystalline aluminosilicate materials comprised of a series of strictly uniform channels and cavities repeating along the tri-directional structure of the lattice. Over the last 30 years, researchers have increasingly recognized the desirable properties of these materials as hosts for photochemical reactions. This review will endeavor to draw attention to the properties of zeolite materials that make them appealing substrates for hosting guest molecules during photochemical reactions. An overview of some classical examples in zeolite host-guest photochemistry will be presented along with a brief description of a new use for zeolite materials as protective encapsulators.

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Lactone-Derived Carbon-Centered Radicals: Formation and Reactivity with Oxygen

Cited by 81 publications

References 21 publications

Stability of carbon‐centered radicals: Effect of functional groups on the energetics of addition of molecular oxygen

Stability of carbon‐centered radicals: Effect of functional groups on the energetics of addition of molecular oxygen

Mechanophores with a Reversible Radical System and Freezing‐Induced Mechanochemistry in Polymer Solutions and Gels

Supramolecular photochemistry in zeolites: From catalysts to sunscreens

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