RESUMEN
A highly selective cross-coupling reaction between Si-OAc (AcO = acetoxy) and Si-OH compounds that generates unsymmetrical and symmetrical oligosiloxanes concurrent with the release of acetic acid has been developed. The high selectivity arises from the reactivity difference that depends on the varying number of acetoxy groups present, thus facilitating a clean one-pot synthesis of oligosiloxanes. For instance, the reactions of di-, tri-, or tetraacetoxysilanes with silanols furnish acetoxy-containing di- and trisiloxanes in high yield. Two equivalents of tetraacetoxysilane can react with various silanediols to form 1,1,1,3,3,3-hexaacetoxytrisiloxanes, which subsequently react with a second molecule of a silanediol to selectively afford 1,1,3,3-tetraacetoxycyclotetrasiloxanes. The cyclotetrasiloxanes further react with a third molecule of silanediol to provide unprecedented bicyclic pentasiloxanes with acetoxy groups at the bridgehead silicon atoms. Applications of the acetoxy-containing products as efficient surface-treatment agents and new building blocks for highly heat-resistant materials are demonstrated.
RESUMEN
The series of linear-shaped phenylacetylenyl- and (phenylacetylenyl)phenylacetylenyl-substituted aromatic enediynes 1-3 were synthesized as pure trans and cis isomers and their photochemistry explored. With expansion of the π-electron system, the absorption spectra red-shifted and the molar extinction coefficients dramatically increased up to 122000 M(-1) cm(-1) for trans-3. The absorption spectra of cis-2 and cis-3 consisted of two independent absorption bands. The fluorescence quantum yields of the molecules were high, even for the cis isomers (Φ(f) = 0.39-0.61). The fluorescence decay of each of the compounds was analyzed as a single exponential and the wavelength dependence of time constants was not observed, indicating a single emitting state in all cases. All isomers exhibited mutual cis-trans photoisomerization. The quantum yield of both trans-to-cis and cis-to-trans photoisomerization considerably decreased in 2 and 3, presumably due to an increased number of photochemical processes that yield nonreactive excited species and which result in nonradiative deactivation. Three energy minima exist in the excited triplet state, where the energy of planar conformation decreased with the extension of the phenyl acetylenyl chain, resulting in the promotion of nonradiative processes without conformational change.
Asunto(s)
Enediinos/síntesis química , Fotoquímica , Fluorometría , Espectrometría de Fluorescencia , Espectrofotometría Ultravioleta , EstereoisomerismoRESUMEN
Intramolecularly hydrogen-bonded organic compounds often exhibit fluorescence emission at considerably longer wavelengths than typical fluorescence as a result of excited-state intramolecular proton transfer (ESIPT). The structure-property relationship of such ESIPT molecules, however, remains obscure. The present article reports the excited-state dynamics of a new family of ESIPT molecules, 2-(2'-hydroxynaphthyl)benzazoles 1-3, based on steady-state and time-resolved spectroscopy measurements. In comparison with the parent compound HBO, all three compounds 1-3 exhibited absorption bands at longer wavelengths and emitted fluorescence from the excited keto-tautomer K* at shorter wavelengths, indicating that the introduction of a naphthalene ring increases the energy gap between the ground and excited states for the keto-tautomer despite the expansion of the aromatic ring. Time-resolved fluorescence spectra revealed dual emission for compounds 1 and 3, consisting of two distinct fluorescence bands originating from K* and the excited rotamer E'*, whereas 2 exhibited fluorescence only from the K* state. In the transient absorption spectra, both the T-T absorption band and the ground state absorption band of the Z-keto tautomer were observed for 1, whereas only the T-T absorption band was observed for 2 and only the Z-keto tautomer band was observed for 3.
RESUMEN
Rhizopus oryzae MYA-2483, which cannot utilize D-psicose as a sole source of carbon, converted D-psicose to two other compounds. These compounds were identified by NMR and IR as D-tagatose and D-talitol. In this study, we describe for the first time the bioconversion of D-psicose to D-tagatose. Various strains of Mucoraceae fungi, to which R. oryzae MYA-2483 belongs, exhibited conversion activity similar to that of R. oryzae MYA-2483. There is the possibility that a considerable number of fungi belonging to Mucoraceae possess such D-psicose conversion activity.
Asunto(s)
Biotecnología/métodos , Fructosa/química , Hongos/metabolismo , Hexosas/química , Rhizopus/metabolismo , Alcoholes del Azúcar/química , Conformación de Carbohidratos , Carbohidrato Epimerasas/química , Medios de Cultivo/metabolismo , Espectroscopía de Resonancia MagnéticaRESUMEN
The effect of the rare sugar D-psicose on chitosan production by Rhizopus oryzae was studied. The fungus was not able to utilize D-psicose as a sole source of carbon, either for germination of the spores or for growth of the vegetative cells. In a medium containing a low amount of D-glucose, however, D-psicose supplementation between 5 and 12 g/l caused enhancement of the productivity of chitinous substances, especially chitosan, in the cell walls. Substantial changes in the chitosan molecule were not observed from FT-IR or 1H NMR data. It was inferred that a percentage age of the D-psicose added was transformed into another rare sugar tentatively identified as D-tagatose. It was concluded that D-psicose activates the synthesis of chitosan in the cell walls probably through its transformation into another sugar such as D-tagatose.