Ternary hybrid material formation by twin polymerization coupled with the bis-epoxide/amine step growth polymerization

“…APSI reacts in a twin polymerization in presence of BADGE reactant to a hybrid network consisting of a phenolic resin and a bisphenol A‐based polydialkylsiloxane (Scheme ) . As the monomer ratio of conventional epoxy and amine curing agent determines the mechanical and thermal properties of the resulting thermosetting polymer, BADGE was cured with APSI at two different compositions — BADGE/APSI 1:1 and 1:2.…”

“…Twin polymerization of BADGE and APSI yields an inorganic–organic hybrid material featuring increased thermal stability depending on the composition and curing temperature . Moreover, SiO 2 formation while combustion gives higher residual mass.…”

“…The experimental values correlate with the calculated SiO 2 content (Table ). Slight deviations can be explained by incomplete polymerization of the polydialkylsiloxane or formation of cyclic siloxanes that evaporate during the heating process .…”

“…It can be polymerized thermally and reacts to a phenolic resin and a polydialkylsiloxane with pendant primary amino groups still accessible for reaction with electrophilic reagents . Thus, the reaction of amino functionalized TM (APSI) and commercially available bisphenol‐A‐diglycidylether (BADGE) (Scheme ) leads to the formation of a nanostructured and crosslinked epoxide/amine, phenolic resin and polydialkylsiloxane network .…”

Basalt fiber reinforced polymers with improved thermal and mechanical properties by combination of twin polymerization with epoxide chemistry

“…APSI reacts in a twin polymerization in presence of BADGE reactant to a hybrid network consisting of a phenolic resin and a bisphenol A‐based polydialkylsiloxane (Scheme ) . As the monomer ratio of conventional epoxy and amine curing agent determines the mechanical and thermal properties of the resulting thermosetting polymer, BADGE was cured with APSI at two different compositions — BADGE/APSI 1:1 and 1:2.…”

“…Twin polymerization of BADGE and APSI yields an inorganic–organic hybrid material featuring increased thermal stability depending on the composition and curing temperature . Moreover, SiO 2 formation while combustion gives higher residual mass.…”

“…The experimental values correlate with the calculated SiO 2 content (Table ). Slight deviations can be explained by incomplete polymerization of the polydialkylsiloxane or formation of cyclic siloxanes that evaporate during the heating process .…”

“…It can be polymerized thermally and reacts to a phenolic resin and a polydialkylsiloxane with pendant primary amino groups still accessible for reaction with electrophilic reagents . Thus, the reaction of amino functionalized TM (APSI) and commercially available bisphenol‐A‐diglycidylether (BADGE) (Scheme ) leads to the formation of a nanostructured and crosslinked epoxide/amine, phenolic resin and polydialkylsiloxane network .…”

Basalt fiber reinforced polymers with improved thermal and mechanical properties by combination of twin polymerization with epoxide chemistry

“…熱硬化性樹脂であるエポキシ樹脂は、接着力、寸 法安定性等の優れた機械的特性に加え、優れた耐薬 品性および絶縁性を有する機能性材料として知ら れている [1,2]。しかしながら、この材料は、可燃性 が高い、もろい、などといった欠点も持ち合わせて いる。これらの欠点を補うため、今日では硬化剤や 充填剤の添加による改善が行われている [3,4]。硬化 剤には様々な種類があり、一般的にリン系化合物 [5][6][7][8]、ホウ素系化合物 [9,10]、チオール系化合物 [11,12] および窒素化合物 [13][14][15]などが知られている。窒素 化合物系硬化剤の一つにイミダゾールがある。イミ ダゾールを用いて硬化物を合成した場合、生成した 硬化物は、耐熱性および高い機械的強度を持ち合わ せることが知られている [16]。 また、 イミダゾールに 官能基を付加させることにより、硬化反応性を変化 させることが可能となり、常温での混合時の安定性 を高めることができる [17][18][19]。さらに、室温での可 使時間が比較的長く、高温で硬化したものは機械的 化学的性質に優れていることから、イミダゾールは 優れた硬化剤として利用されている [20]。 一方で、 イミダゾールを硬化剤として用いたエポ キシ-イミダゾール樹脂の硬化反応に関する反応 機構を検討した研究は少なく [16,[20][21][22][23]…”

エポキシ－イミダゾール樹脂の硬化反応の反応機構に関する理論的研究

Ternary hybrid materials based on the photoinduced cationic polymerization of functional twin monomer and epoxides