Phthalonitrile monomer with alkyl, pyrimidine, and amino is successfully prepared by nucleophilic substitution. The monomer is cured by autocatalysis of active hydrogen in the amino group, in order to obtain polymers through different temperature procedures. The low melting point (96°C) and curing kinetics of the monomer are analyzed by DSC, which manifest a processing window of 163°C. With lower energy barriers to overcome, the apparent activation energy (Ea) is 59.6 kJ mol−1 after fitting and calculating, signifying that the monomers are easier to process into polymers. This study focuses on the usefulness of the polymer, especially the long-term thermal stability by the comparison of numerous commonly used polymers. The consequence demonstrates that the polymer could be used for long periods at 300°C, keeping weight loss within 5 wt.% for 6 h. The advantage of long-term usage at high temperatures has not been proved in previous works on phthalonitrile polymer. Moreover, the thermal and thermal-mechanical stability are examined through TGA and DMA. The results indicate preferable thermal properties, that the glass transition temperature is up to 400°C.
SchusterMKreuerKDAndersenHT, et al.Sulfonated poly (phenylene sulfone) polymers as hydrolytically and thermooxidatively stable proton conducting ionomers. Macromolecules2007; 40: 598–607.
2.
LiuTXuMBaiZ, et al.Toughening effect of self-assembled thermoplastic particles on phthalonitrile containing benzoxazine and improved mechanical properties in the presence of fibers reinforcement. Polymer2022; 260: 125355.
3.
LaskoskiMDominguezDDKellerTM. Alkyne-containing phthalonitrile resins: Controlling mechanical properties by selective curing. J Polym Sci Part A: Polym Chem2013; 51: 4774–4778.
LaskoskiMDominguezDDKellerTM. Synthesis and properties of a bisphenol A based phthalonitrile resin. J Polym Sci A Polym Chem2005; 43: 4136–4143.
6.
WangMNingY. Oligosilylarylnitrile: the thermoresistant thermosetting resin with high comprehensive properties. ACS Appl Mater Interfaces2018; 10: 11933–11940.
7.
LaskoskiMKellerTMRickslaskoskiHL, et al.Improved synthesis of oligomeric sulfone-based phthalonitriles. Macromol Chem Phys2015; 216: 1808–1815.
8.
XuMRenDChenL, et al.Understanding of the polymerization mechanism of the phthalonitrile-based resins containing benzoxazine and their thermal stability. Polymer2018; 143: 28–39.
9.
ChenXShanSLiuJ, et al.Synthesis and properties of high temperature phthalonitrile polymers based on o, m, p-dihydroxybenzene isomers. RSC Adv2015; 5: 80749–80755.
10.
ZhaoFLiuRKangC, et al.A novel high-temperature naphthyl-based phthalonitrile polymer: synthesis and properties. RSC Adv2014; 4: 8383–8390.
11.
WangHWangJGuoH, et al.A novel high temperature vinylpyridine-based phthalonitrile polymer with a low melting point and good mechanical properties. Polym Chem2018; 9: 976–983.
12.
ZhangXWangXLiJ, et al.Synthesis of pyridine heterocyclic low-melting-point phthalonitrile monomer and the effects of different curing agents on resin properties. Polymers2022; 14: 4700.
13.
BaiSSunXZhangZ, et al.Synthesis and properties of a low melting point phthalonitrile resin containing high density nitrile groups. ChemistrySelect2020; 5: 265–269.
14.
WuMHanWZhangC, et al.Rational design of fluorinated phthalonitrile/hollow glass microsphere composite with low dielectric constant and excellent heat resistance for microelectronic packaging. Nanomaterials2022; 12: 3973.
15.
WuMXuJBaiS, et al.A high-performance functional phthalonitrile resin with a low melting point and a low dielectric constant. Soft Matter2020; 16: 1888–1896.
16.
WangGHanYGuoY, et al.Phthalonitrile-terminated silicon-containing oligomers: synthesis, polymerization, and properties. Ind Eng Chem Res2019; 58: 9921–9930.
17.
HuJHuYDengS F, et al.Synthesis and properties of a novel silicon-containing phthalonitrile resin and its quartz-fiber-reinforced composites. High Perform Polym2020; 32: 1112–1121.
18.
HanYTangDHWangGX, et al.Phthalonitrile resins derived from vanillin: synthesis, curing behavior, and thermal properties. Chin J Polym Sci2020; 38: 72–83.
19.
DyatkinBOstiN CSmithR W, et al.Chemical structure and curing dynamics of bisphenol S, PEEK TM ‐like, and resveratrol phthalonitrile thermoset resins. J Polym Sci (2020)2020; 58: 3419–3431.
20.
LaskoskiMClarkeJ SNealA, et al.Sustainable high-temperature phthalonitrile resins derived from resveratrol and dihydroresveratrol. ChemistrySelect2016; 1: 3423–3427.
21.
ZhouTXiaoHPengW, et al.Study on pyrolysis behaviors of L-tyrosine-based phthalonitrile resin. Polym Test2020; 86: 106506.
22.
YeJLiQZhangS, et al.Melamine modified phthalonitrile resins: Synthesis, polymerization and properties. Polymer2022; 256: 125156.
23.
LiuTYangYWangT, et al.Synthesis and properties of poly (aryl ether ketone)-based phthalonitrile resins. Polym Eng Sci2014; 54: 1695–1703.
24.
LeiWWangDLiY, et al.High temperature resistant polymer foam based on bi-functional benzoxazine-phthalonitrile resin. Polym Degrad Stab2022; 201: 110003.
25.
PuYXieHHeX, et al.The curing reaction of phthalonitrile promoted by sulfhydryl groups with high curing activity. Polymer2022; 252: 124948.
26.
LiuYJiPZhangZ, et al.Synthesis and properties of pyrazine-based oligomeric phthalonitrile resins. High Perform Polym2019; 31: 1075–1084.
27.
YangKChenXZhangZ, et al.Introducing rigid pyrimidine ring to improve the mechanical properties and thermal-oxidative stabilities of phthalonitrile resin. Polym Adv Technol2019; 31: 328–337.
28.
XiZChenXYuX, et al.Synthesis and properties of a novel high temperature pyridine-containing phthalonitrile polymer. J Polym Sci Part A: Polym Chem2016; 54: 3819–3825.
29.
PengWYaoFHuJ, et al.Renewable protein-based monomer for thermosets: a case study on phthalonitrile resin. Green Chem2018; 20: 5158–5168.
30.
WangCGuanYTianD, et al.Highly transparent polyimides derived from 2-phenyl-4,6-bis(4-aminophenoxy) pyrimidine and 1, 3-bis-(5-amino-2-pyridinoxy) benzene: preparation, characterization, and optical properties. RSC Adv2015; 5: 103246–103254.
31.
ZhangSLiYWangX, et al.Synthesis and properties of novel polyimides derived from 2,6-bis(4-aminophenoxy-4'-benzoyl) pyridine with some of dianhydride monomers. Polymer2005; 46: 11986–11993.
32.
WangXLiYFMaT, et al.Synthesis and characterization of novel polyimides derived from 2,6-bis[4-(3,4-dicarboxyphenoxy) benzoyl] pyridine dianhydride and aromatic diamines. Polymer2006; 47: 3774–3783.
33.
YuXYNaitoKKangC, et al.Synthesis and properties of a high-temperature naphthyl-based phthalonitrile polymer. Macromol Chem Phys2013; 214: 361–369.
34.
ShengHPengXGuoH, et al.Synthesis and thermal properties of a novel high temperature alkyl-center-trisphenolic-based phthalonitrile polymer. Mater Chem Phys2013; 142: 740–747.
35.
DayoAQCaoXmCaiWa, et al.Synthesis of benzophenone-center bisphenol-A containing phthalonitrile monomer (BBaph) and its copolymerization with P-a benzoxazine. React Funct Polym2018; 129: 46–52.
36.
PengXShengHGuoH, et al.Synthesis and properties of a novel high-temperature diphenyl sulfone-based phthalonitrile polymer. High Perform Polym2014; 26: 837–845.
BaiSSunXWuM, et al.Effects of pure and intercalated halloysites on thermal properties of phthalonitrile resin nanocomposites. Polym Degrad Stab2020; 177: 109192.
39.
YueJZhaoCDaiY, et al.Catalytic effect of exfoliated zirconium phosphate on the curing behavior of benzoxazine. Thermochim Acta2017; 650: 18–25.
40.
Van KrevelenDW. Some basic aspects of flame resistance of polymeric materials. Polymer1975; 16: 615–620.
