Monomer-Dimer Equilibrium of Rhodamine B Encapsulated in Si–Al and Si–Ti Binary-Oxide Thin Films

Si—Al and Si—Ti binary-oxide thin films including Rhodamine B (RB) have been prepared. They were dip-coated as a function of time after mixing of each sol-gel reaction system. The absorption and fluorescence spectra of the individual films have been observed. These spectra were analyzed in order to clarify the behavior of RB along with the change in the environment around the RB molecules, caused by the progress of the sol-gel reaction, in the fluid sol and the prepared thin films. Some amount of the RB dimers (H- and J-types) were formed in the Si—Al and Si—Ti binary-oxide films (Si : M = 75 : 25) prepared at the initial stage of the sol-gel reaction and aged under relative humidity of 60%. In the case of Si—Al binary-oxide films, the amount of the J-dimer decreased along with the reaction time at which the films were prepared, indicating that growing polymer networks of metal alkoxides around the RB molecules prevent the formation of the J-dimer. On the other hand, larger amounts of the H- and J-dimers were formed in the Si—Ti binary-oxide films prepared at longer reaction time of the solution. RB interacts more strongly with —TiOH compared with —AlOH. In the case of the Si—Ti binary-oxide films, with the progress of the sol-gel reaction, RB molecules in the prepared films easily cohere around the —TiOH and form the dimers because of increase in the amount of the —TiOH and contraction in the volume of the spaces where RB molecules exist.     

Photoresponsive Peptide and Polypeptide Systems, 14. Biodegradation of Photocrosslinkable Copolypeptide Hydrogels Containing L‐Ornithine and δ‐7‐Coumaryloxyacetyl‐L‐ornithine Residues

Copoly[Orn/Orn(Cou)] containing δ‐7‐coumaryloxyacetyl‐L ‐ornithine [Orn(Cou)] and L ‐ornithine (Orn) residues was synthesized by the N‐carboxyanhydride method. When aqueous solutions of copoly[Orn/Orn(Cou)] containing 5–10 mol‐% of Orn(Cou) are irradiated, the photoinduced dimerization reaction between coumarin moieties in the side chains proceeds slowly, and after 24 h the solutions become transparent hydrogels. The gels exhibit solvent‐induced reversible expansion and contraction behavior in both water and ethanol. The biodegradation of the hydrogels by proteolytic enzymes and soil filamentous fungi is investigated using photocrosslinked copoly[Orn/Orn(Cou)] gels. The copoly[Orn⁸⁹/Orn(Cou)¹¹] gel is degradable by protease type XXIII, but not by trypsin. In the biochemical oxygen demand test, the order of the microbial biodegradation (%) was Rhizopus sp. (92%) > A. oryzae (38%) > P. caseicolum (18%) > P. citrinum (11%) > Cladosporium sp. (6%). The order for the copoly[Orn⁸⁹/Orn(Cou)¹¹] hydrogel is inverse to that for a polylysine/glutaraldehyde gel. These results suggest that the biodegradabilities of photocrosslinked hydrogels can be controlled by the monomer ratio of Orn, Orn(Cou) and lysine (Lys) in the parent copoly(amino acid)s of the photocrosslinked hydrogels.     

Synthesis,characterization, and physical properties of new copolymers of poly(amino acid)–urethane—copolymers of γ‐methyl‐L‐glutamate‐N‐carboxyanhydride and urethane prepolymer

New copolymers of amino acid and urethane (PAU), in which a polyurethane segment was combined with poly(γ‐methyl‐L‐glutamate) (PMLG) of various contents, were synthesized by the copolymerization of the polyurethane prepolymer (UPP) having isocyanate groups at both terminals of the chain and γ‐methyl‐L ‐glutamate‐N‐carboxyanhydride (NCA) to improve the elastic recovery and adhesion of PMLG for application of PMLG to synthetic leather. The copolymerization of the UPP with NCA was carried out by applying the reactivity of isocyanate and the polymerization mechanism of NCA using the primary amine and tertiary amine as initiators. Infrared (IR) and ¹³C‐NMR spectra of these PAUs as well as the chemical analysis of the PAU intermediates showed that the PAUs would have a multiblock–triblock structure: namely, the PAUs consisted of the block copolymer segments of urethane and a small amount of PMLG at the center of the copolymer chain and most of the PMLG at both terminals of the copolymer chain. The elastic recovery and adhesion of these PAUs were significantly larger than those of the PMLG with the maintenance of a good sense of touch, which was a unique asset of PMLG. Furthermore, it was found that the PAUs had intermediary moisture permeability between that of PMLG and polyurethane. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 383–389, 1999     

Polycondensation of Terephthalic Acid and 3,3′‐Dimethyl Bisphenol A with TsCl/DMF/Py in the Presence of Salts

When activated with TsCl/dimethylformamide/pyridine in the presence of lithium, ammonium, or phosphonium salts, activated terephthalic acid of difficult solubility in pyridine became soluble. Depending on the kind and amount of the salt, terephthalic acid reacted smoothly with 3,3′‐dimethyl bisphenol A to yield the corresponding polymer having high molecular weight. However, this reaction could not be successfully applied to the preparation of polyesters from other dicarboxylic acids of difficult solubility.     

Molecular orientation of paramagnetic metal complex by melt-drawing thermotropic liquid crystalline polymers

New liquid-crystalline polyesters and paramagnetic vanadyl complex were prepared as host polymer and guest complex. Melt-drawn fibers were made from the blend of host polymer and guest complex at the mesophase temperature. ESR spectra of the melt-drawn fibers indicated that the base of pyramidal vanadyl complex is completely oriented parallel to the fiber axis.     

Beyond Reduction Cocatalysts: Critical Role of Metal Cocatalysts in Photocatalytic Oxidation of Methane with Water**

Environmentally sustainable and selective conversion of methane to valuable chemicals under ambient conditions is pivotal for the development of next-generation photocatalytic technology. However, due to the lack of microscopic knowledge about non-thermal methane conversion, controlling and modulating photocatalytic oxidation processes driven by photogenerated holes remain a challenge. Here, we report novel function of metal cocatalysts to accept photogenerated holes and dominate selectivity of methane oxidation, which is clearly beyond the conventional concept in photocatalysis that the metal cocatalysts loaded on the surfaces of semiconductor photocatalysts mostly capture photogenerated electrons and dominate reduction reactions exclusively. The novel photocatalytic role of metal cocatalysts was verified by operando molecular spectroscopy combined with real-time mass spectrometry for metal-loaded Ga₂O₃ model photocatalysts under methane and water vapor at ambient temperature and pressure. Our concept of metal cocatalysts that work as active sites for both photocatalytic oxidation and reduction provides a new understanding of photocatalysis and a solid basis for controlling non-thermal redox reactions by metal-cocatalyst engineering.