Design of P-decorated POSS towards flame-retardant, mechanically-strong, tough and transparent epoxy resins

• Published in: Journal of colloid and interface science Vol. 640; pp. 864 - 876
• Main Authors: Wu, Tao, Yang, Feihao, Tao, Jie, Zhao, Hai-Bo, Yu, Chuanbai, Rao, Wenhui
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 15.06.2023
• Subjects: Epoxy resin; Flame retardancy; Mechanical reinforcement; Polysilsesquioxane; Transparency; Epoxy resin; Flame retardancy; Polysilsesquioxane; Transparency; Mechanical reinforcement
• ISSN: 0021-9797; 1095-7103
• DOI: 10.1016/j.jcis.2023.03.022

[Display omitted] •The combination of the inorganic structure with the flexible aliphatic segment was proposed to fabricate P-decorated POSS.•Epoxy resins with P-decorated POSS maintained high transparency.•The resultant P-decorated POSS showed both high flame retardancy and mechanical reinforcement for epoxy resins.•The specific mechanism of action was analyzed. Epoxy resins (EPs) are known for their durability, strength, and adhesive properties, which make them a versatile and popular material for use in a variety of applications, including chemical anticorrosion, small electronic devices, etc. However, EP is highly flammable due to its chemical nature. In this study, phosphorus-containing organic–inorganic hybrid flame retardant (APOP) was synthesized by introducing 9, 10-dihydro-9-oxa-10‑phosphaphenathrene (DOPO) into cage-like octaminopropyl silsesquioxane (OA-POSS) via Schiff base reaction. The improved flame retardancy of EP was achieved by combining the physical barrier of inorganic Si-O-Si with the flame-retardant capability of phosphaphenanthrene. EP composites containing 3 wt% APOP passed the V-1 rating with a value of LOI of 30.1% and showed an apparent reduction in smoke release. Additionally, the combination of the inorganic structure and the flexible aliphatic segment in the hybrid flame retardant provides EP with molecular reinforcement, while the abundance of amino groups facilitates a good interface compatibility and outstanding transparency. Accordingly, EP containing 3 wt% APOP increased in tensile strength, impact strength, and flexural strength by 66.0 %, 78.6 %, and 32.3 %, respectively. The EP/APOP composites had a bending angle lower than 90°, and their successful transition to a tough material highlights the potential of this innovative combination of the inorganic structure and the flexible aliphatic segment. In addition, the relevant flame-retardant mechanism revealed that the APOP promoted the formation of a hybrid char layer containing P/N/Si for EP and produced phosphorus-containing fragments during combustion, showing flame-retardant effects in both condensed and vapor phases. This research offers innovative solutions for reconciling flame retardancy & mechanical performances and strength & toughness for polymers.