氰酸酯
玻璃化转变
单体
低聚物
氰酸盐
材料科学
高分子化学
产量(工程)
三元运算
丙烷
聚合物
溶剂
稀释剂
化学工程
化学
有机化学
复合材料
环氧树脂
工程类
计算机科学
程序设计语言
作者
Alasdair O. Crawford,Gabriel Cavalli,Brendan J. Howlin,Ian Hamerton
标识
DOI:10.1016/j.reactfunctpolym.2016.03.002
摘要
Three cyanate ester monomer or oligomer species: 2,2-bis(4-cyanatophenyl)propane 1, 1-1-bis(4-cyanatophenyl)ethane (2), and the oligomeric phenolic cyanate (Primaset™ PT30) (3), are blended in various ratios with bis(4-maleimidophenyl)methane, (4), to form binary and ternary mixtures (11 in total) and cured, in the absence of catalysts (3 K min− 1 to 150 °C + 1 h; 3 K min− 1 to 200 °C + 3 h), followed by a post cure (3 K min− 1 to 260 °C + 1 h). The use of liquid monomer, (2), offers the possibility of liquid processing in blends containing minority compositions of bismaleimide. Glycidylmethacrylate is explored as a reactive diluent (2.5–10 wt%) to linked interpenetrating network polymer structures comprising cyanate ester and bismaleimide components with glass transition temperatures of 267–275 °C, depending on composition; the onset of thermo-oxidative degradation ranges from 386 to 397 °C. When a binary blend of (2) and (3) (with the former in the minority) is co-cured with (4), an excellent balance of properties is achieved with liquid processing, a Tg > 400 °C and onset of degradation of 425 °C in static air. Kinetic analysis of DSC data using Ozawa and Kissinger methods yield activation energies of between 107 and 112 kJ/mol for a binary blend of (1)90-(4)10, which is in good agreement with literature. Molecular dynamics simulation of the same blend in cured form gave a simulated glass transition temperature of 250 °C that is in very close agreement with empirical DMTA data.
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