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A new concept for controlling the energy level of conjugated materials without extending the π-conjugated system is described. By performing aza-substitution at the “isolated frontier molecular orbitals (FMOs)”, which are defined in this manuscript, one energy level of FMOs can be selectively and efficiently lowered. Based on this protocol, advanced conjugated polymers with pure-blue or near-infrared luminescent properties were obtained.
For uniform and flat materials, heavier plates show higher sound insulation performance because of the mass law. Acoustic metamaterials with periodic resonance structures have attracted attention as ultra-lightweight sound insulators that can break the mass law limit. Recently, practical acoustic metamaterial sheets that allow high-throughput fabrication and single-step implementation on target objects have been developed based on polymer materials. In this Focus Review, the polymer-based material design, the control of acoustic functions based on polymer properties, and applications as sound insulators and vibration dampers are described.
Tributylborane-initiated graft polymerization of methyl methacrylate on a poly(vinylidene fluoride) film was successfully achieved. The reaction was affected by the temperature and concentration of tributylborane, and a 41% graft yield was obtained under the optimized conditions. This value was higher than those obtained with other methods. This method facilitated modifications of only the surface of the poly(vinylidene fluoride) film, which was confirmed by IR spectroscopy and cross-section observations. New physical properties were added to the surface, such as hydrophilicity.
Elastic moduli of nano-dispersed elastomer domains in injection molded isotactic polypropylene (iPP)/ethylene-co-octene elastomer (EO) binary blends were investigated by an atomic force microscopy. The EO domains were highly elongated to the flow direction. The elastic modulus distribution of the EO domains was quite different depending on the annealing conditions.
The effect of radiation-induced graft polymerization (RIGP) on abaca fibers was evaluated for composite reinforcement. Using grafted fibers improved composite properties, especially when RIGP was carried out under reversible addition-fragmentation chain transfer (RAFT) mechanism. Controlled chain growth of grafted polymer could be achieved by RAFT-RIGP and this led to the highest improvement in mechanical strength versus pristine fibers and those modified by conventional RIGP. These findings show the capability of RAFT-RIGP to optimize the effectiveness of natural fibers in the composite industry.
This study explores enhanced electrical properties in conductive polymers, particularly PEDOT:PSS, by creating multilayered films. Initial findings show a sheet resistance of 1639 Ω□-1 for a single layer, but applying three additional layers reduces it to 29 Ω□-1, boosting conductivity from 2.6 to 18.3 Scm-1. Similar improvements are observed with formulations containing Tween 80. Analysis via X-ray diffraction and Raman spectroscopy indicates increased crystalline order and a benzoid to quinoid shift. Surface profiling reveals growing roughness with additional PEDOT:PSS layers, partially mitigated by Tween 80.
Poly(dopamine) (PDA) was investigated as a primer to enhance adhesion in flexible optoelectronic devices using the conducting polymer PEDOT:PSS. PDA improved wettability on polypropylene (PP) but reduced it on poly(ethylene terephthalate) (PET). However, PDA enhanced the quality and adhesion of pristine PEDOT:PSS and PEDOT:PSS/Tween 80 films on glass, PP, and PET. Crucially, it did not negatively affect sheet resistance of PEDOT:PSS/Tween 80 films, establishing its suitability as a primer for flexible substrates. This research addresses a key challenge in utilizing PEDOT:PSS in flexible optoelectronics, enhancing its performance on various substrates.
We determined intrinsic viscosity for polystyrene (PS) samples with a wide range of molecular weight in d-limonene, which attracts interest as an environmentally friendly solvent for PS. By analyzing the experimental data obtained in d-limonene using the helical wormlike chain model with and without the excluded-volume effect, solvent quality of d-limonene for PS was quantitatively evaluated. Consequently, it was concluded that d-limonene belongs to the category of medium solvent, which is intermediate between good solvents like toluene and poor solvents like cyclohexane, for PS.
