Your search keyword '"Del Giacco, Tiziana"' showing total 5 results

1. Competition Between C α -S and C α -C β Bond Cleavage in β-Hydroxysulfoxides Cation Radicals Generated by Photoinduced Electron Transfer.

Author

Lapi A, D'Alfonso C, Del Giacco T, and Lanzalunga O

Subjects

Cations chemistry, Free Radicals chemistry, Molecular Structure, Oxidation-Reduction, Electrons

Abstract

A kinetic and product study of the 3-cyano-N-methyl-quinolinium photoinduced monoelectronic oxidation of a series of β-hydroxysulfoxides has been carried out to investigate the competition between C α -S and C α -C β bond cleavage within the corresponding cation radicals. Laser flash photolysis experiments unequivocally established the formation of sulfoxide cation radicals showing their absorption band (λ max ≈ 520 nm) and that of 3-CN-NMQ • (λ max ≈ 390 nm). Steady-state photolysis experiments suggest that, in contrast to what previously observed for alkyl phenyl sulfoxide cation radicals that exclusively undergo C α -S bond cleavage, the presence of a β-hydroxy group makes, in some cases, the C α -C β scission competitive. The factors governing this competition seem to depend on the relative stability of the fragments formed from the two bond scissions. Substitution of the β-OH group with -OMe did not dramatically change the reactivity pattern of the cation radicals thus suggesting that the observed favorable effect of the hydroxy group on the C α -C β bond cleavage mainly resides on its capability to stabilize the carbocation formed upon this scission., (© 2021 The Authors. Photochemistry and Photobiology published by Wiley Periodicals LLC on behalf of American Society for Photobiology.)

Published

2021

2. Photoinduced One-Electron Oxidation of Benzyl Methyl Sulfides in Acetonitrile: Time-Resolved Spectroscopic Evidence for a Thionium Ion Intermediate.

Author

Bettoni M, Del Giacco T, Stradiotto M, and Elisei F

Subjects

Ions chemistry, Lasers, Molecular Structure, Oxidation-Reduction, Photochemical Processes, Quantum Theory, Spectrum Analysis, Time Factors, Acetonitriles chemistry, Benzyl Compounds chemistry, Electrons, Quaternary Ammonium Compounds chemistry, Sulfides chemistry

Abstract

The photo-oxidation of 4-methoxybenzyl methyl sulfide (1a), benzyl methyl sulfide (1b), and 4-cyanobenzyl methyl sulfide (1c) has been investigated in the presence of N-methoxy phenanthridinium hexafluorophosphate (MeOP(+)PF6(-)) under nitrogen in CH3CN. The steady-state photolysis experiments showed for the investigated sulfides exclusively the formation of the corresponding benzaldehyde as the oxidation product, reasonably due to a deprotonation of the sulfide radical cations. Photo-oxidation of 1a-1c occurs through an electron transfer process. Indeed, laser flash photolysis measurements showed an efficient formation of sulfide radical cations, detected in their dimeric form [(4-X-C6H4CH2SCH3)2(+•)] at ≈520 nm. At longer delay times, the absorption of the dimer radical cation was replaced by an absorption band assigned to the (α-thio)benzyl cation (thionium ion, λmax = 420-400 nm), formed by oxidation of the benzyl radical and not by that of the (α-thiomethyl)benzyl radical, as expected if a Cα-H bond cleavage is operative. This finding highlights a particular stability of this kind of cation never reported before, even though its involvement in one-electron oxidation mechanisms of various sulfides has already been invoked. Density functional theory calculations allowed identification of a significant charge and spin delocalization involving both the phenyl ring and the sulfur atom of the radical cations.

Published

2015

3. An acridinium-based sensor as a fluorescent photoinduced electron transfer probe for proton detection modulated by anionic micelles.

Author

Basili S, Del Giacco T, Elisei F, and Germani R

Subjects

Aminacrine chemistry, Anions, Electron Transport, Fluorescent Dyes analysis, Free Radicals chemistry, Hydrogen-Ion Concentration, Molecular Structure, Solutions, Aminacrine analogs & derivatives, Electrons, Fluorescent Dyes chemical synthesis, Micelles, Protons, Water chemistry

Abstract

A water-soluble fluorescent pH sensor of 9-amino-10-methylacridinium chromophore with the 2-(diethylamine)ethyl chain as a receptor shows an "off-on" response going from basic to acidic solution. Photoinduced electron transfer has been directly demonstrated to be the quenching mechanism by the observation of the long-lived acridinyl radical. The interaction of the protonated sensor with anionic micelles causes a significant increase in the detection sensitivity of pH.

Published

2014

4. Competition Between Cα‐S and Cα‐Cβ Bond Cleavage in β‐Hydroxysulfoxides Cation Radicals Generated by Photoinduced Electron Transfer†.

Author

Lapi, Andrea, D'Alfonso, Claudio, Del Giacco, Tiziana, and Lanzalunga, Osvaldo

Subjects

SCISSION (Chemistry), FLASH photolysis, CARBOCATIONS, RADICAL cations, PERMUTATION groups, ELECTRONS

Abstract

A kinetic and product study of the 3‐cyano‐N‐methyl‐quinolinium photoinduced monoelectronic oxidation of a series of β‐hydroxysulfoxides has been carried out to investigate the competition between Cα‐S and Cα‐Cβ bond cleavage within the corresponding cation radicals. Laser flash photolysis experiments unequivocally established the formation of sulfoxide cation radicals showing their absorption band (λmax ≈ 520 nm) and that of 3‐CN‐NMQ• (λmax ≈ 390 nm). Steady‐state photolysis experiments suggest that, in contrast to what previously observed for alkyl phenyl sulfoxide cation radicals that exclusively undergo Cα‐S bond cleavage, the presence of a β‐hydroxy group makes, in some cases, the Cα‐Cβ scission competitive. The factors governing this competition seem to depend on the relative stability of the fragments formed from the two bond scissions. Substitution of the β‐OH group with ‐OMe did not dramatically change the reactivity pattern of the cation radicals thus suggesting that the observed favorable effect of the hydroxy group on the Cα‐Cβ bond cleavage mainly resides on its capability to stabilize the carbocation formed upon this scission. [ABSTRACT FROM AUTHOR]

Published

2021

5. Sulfur Radical Cations. Kinetic and Product Study of the Photoinduced Fragmentation Reactions of (Phenylsulfanylalkyl) trimethylsilanes and Phenylsulfanylacetic Acid Radical Cations.

Author

Baciocchi, Enrico, Del Giacco, Tiziana, Elisei, Fausto, and Lapit, Andrea

Subjects

*CATIONS, *SULFUR, *DECARBOXYLATION, *DEUTERIUM, *ISOTOPES, *HYDROGEN bonding, *ELECTRONS, *CHARGE exchange

Abstract

Laser and steady-state photolysis, sensitized by NMQ+, of PhSCH(R)X 1–4 (R = H, Ph; X=SiMe3, CO2H) was carried out in CH3CN. The formation of 1+•-4+• was clearly shown. All radical cations undergo a fast first-order fragmentation reaction involving C-Si bond cleavage with 1+• and 2+• and C-C bond cleavage with 3+• and 4+•. The desilylation reaction of 1+• and 2+• was nucleophilically assisted, and the decarboxylation rates of 3+• and 4+• increased in the presence of H2O. A deuterium kinetic isotope effect of 2.0 was observed when H2O was replaced by D2O. Pyridines too were found to accelerate the decarboxylation rate of 3+• and 4+•. The rate increase, however, was not a linear function of the base concentration, but a plateau was reached. A fast and reversible formation of a H-bonded complex between the radical cation and the base is suggested, which undergoes C-C bond cleavage. It is probable that the H-bond complex undergoes first a rate determining proton-coupled electron transfer forming a carboxyl radical that then loses CO2. The steady-state photolysis study showed that PhSCH3 was the exclusive product formed from 1 and 3 whereas [PhS(Ph)CH-]2 was the only product with 3 and 4. [ABSTRACT FROM AUTHOR]

Published

2006