Nucleophilic trapping of intermediates in the singlet oxygenations of isomeric 1,4-di-t-butoxy-1,3-butadienes

“…The UV absorption of the precursor fraction disappeared during the course of the 1 -h photolysis. Furthermore, irradiation of the precursor fraction for 1 h after it had been separated from most of the unreacted ammonia and acetylene also gave an HCN yield comparable to an 8-h photolysis at room temperature (Table III, run 5). These experiments establish that precursors to HCN condense from the photolysis mixture at 178 K, thus explaining the low yield of HCN at that temperature.…”

“…It was recently suggested that photochemically generated organic polymers should be considered as the source of the chromophores on Jupiter.24 The photopolymerization of acetylene is one source of organic oligomers that absorb visible light (5)(6)(7)(8). HC=CC=CH* + C2H2 -C6H2 + H2 (8) The extent of chromophore formation is decreased markedly by the addition of hydrogen.26 This inhibition is probably due to the rapid rate of reaction of the acetylenic radical intermediates with hydrogen so that they do not react appreciably with the lower concentration of acetylene present. The photochemical condensation of any diacetylene formed by reaction 7 proceeds by excited state and not radical species to form oligomers,27 so this route to chromophores may not be inhibited by hydrogen.…”

Formation of hydrogen cyanide and acetylene oligomers by photolysis of ammonia in the presence of acetylene: applications to the atmospheric chemistry of Jupiter

“…The UV absorption of the precursor fraction disappeared during the course of the 1 -h photolysis. Furthermore, irradiation of the precursor fraction for 1 h after it had been separated from most of the unreacted ammonia and acetylene also gave an HCN yield comparable to an 8-h photolysis at room temperature (Table III, run 5). These experiments establish that precursors to HCN condense from the photolysis mixture at 178 K, thus explaining the low yield of HCN at that temperature.…”

“…It was recently suggested that photochemically generated organic polymers should be considered as the source of the chromophores on Jupiter.24 The photopolymerization of acetylene is one source of organic oligomers that absorb visible light (5)(6)(7)(8). HC=CC=CH* + C2H2 -C6H2 + H2 (8) The extent of chromophore formation is decreased markedly by the addition of hydrogen.26 This inhibition is probably due to the rapid rate of reaction of the acetylenic radical intermediates with hydrogen so that they do not react appreciably with the lower concentration of acetylene present. The photochemical condensation of any diacetylene formed by reaction 7 proceeds by excited state and not radical species to form oligomers,27 so this route to chromophores may not be inhibited by hydrogen.…”

Formation of hydrogen cyanide and acetylene oligomers by photolysis of ammonia in the presence of acetylene: applications to the atmospheric chemistry of Jupiter

“…Additionally, the resonance-delocalized positive charge renders the molecule susceptible to hydration to form hydroperoxyethanol 11 . This step is reminiscent of the reaction of 2,4-hexadienes with 1 O 2 , wherein alcoholysis of the zwitterionic peroxy intermediate provides hydroperoxyalkoxyethenols. − On forming the hydroperoxyethanol 11 , facile rotation about the C2′–C1′ sets up an intramolecular attack by the vinylogous enamine to provide the hydroperoxycyclobutanol 12 . Intermediate 12 subsequently releases hydroperoxyethenol 13 to afford cyanine 3 .…”

Defining the Basis of Cyanine Phototruncation Enables a New Approach to Single-Molecule Localization Microscopy

“…The mechanism involving a charge transfer (path 5, Scheme 14) from the electron rich olefin, 2,3-diaryl-1,4butadiene, to the molecular singlet oxygen to yield the corresponding 2,3-diaryl-1,4-dioxetane was also proposed (94). A similar mechanism was proposed by Clennan for the [2 + 2] cycloaddition of 1 O 2 to 1, 2-di-tert-butoxy-1,3-butadiene (95). In this case, when the solvent was MeOH, the charge transfer mechanism predominates over the concerted [2 s +2 a ] cycloaddition.…”

Singlet Oxygen: Discovery, Chemistry, C₆₀‐Sensitization^†