A high temperature polymer of phthalonitrile‐substituted phosphazene with low melting point and good thermal stability

Zhao, Fenghua; Liu, Ruojin; Yu, Xiaoyan; Naito, Kimiyoshi; Qu, Xiongwei; Zhang, Qingxin

doi:10.1002/app.42606

Cited by 30 publications

(18 citation statements)

References 49 publications

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“…Growth in the aerospace, marine and microelectronic industries increasingly requires the development of heat‐resistant materials . Phthalonitrile (PN)‐based resins, as a class of heat‐resistant materials, have sparked great interest and attention, due to their unique properties, including outstanding thermal stability, great flame retardancy, low moisture resistance and excellent mechanical properties .…”

Section: Introductionmentioning

confidence: 99%

Branched phenyl‐s‐triazine moieties to enhance thermal properties of phthalonitrile thermosets

Zong

et al. 2017

Polymer International

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Heat‐resistant materials have made tremendous progress in marine, aerospace and microelectronic fields. Herein, a new class of phthalonitrile resins, branched poly(biphenyl ether triphenyl‐s‐triazine) phthalonitriles, were successfully synthesized via a two‐step, one‐pot reaction, on the basis of 2,4,6‐tris(4‐fluorophenyl)‐1,3,5‐triazine and 4,4′‐biphenol. 4,4′‐Diaminodiphenylsulfone was employed to facilitate the curing reaction, and successful realization of curing behavior was concluded from rheological and differential scanning calorimetric studies, indicating the obtained resins possess favorable processability. The relationship between concentration of reactants and properties of the resins was systematically studied. After thermal curing, the E‐glass fiber‐reinforced composite, prepared with a concentration of reactants of 0.15 g mL−1, shows an admirable glass transition temperature of 480 °C and commendable thermal stability with 5% weight loss temperature in nitrogen of 563 °C, suggesting that the improvement of the thermal properties stems from the branched structure and the phenyl‐s‐triazine units. © 2017 Society of Chemical Industry

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Section: Introductionmentioning

confidence: 99%

Branched phenyl‐s‐triazine moieties to enhance thermal properties of phthalonitrile thermosets

Zong

et al. 2017

Polymer International

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“…CA‐Ph polymer containing 5 wt% DDS was prepared in an identical manner. A curing agent loading of 5% is commonly employed for curing phthalonitrile resins …”

Section: Methodsmentioning

confidence: 99%

A novel bio‐based phthalonitrile resin derived from catechin: synthesis and comparison of curing behavior with petroleum‐based counterpart

Weng

Wang

et al. 2018

Polymer International

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The development of bio‐based thermosetting resins with good thermal stability can potentially afford sustainable polymers as replacements for petroleum‐based polymers. We report a practical route to a novel catechin‐based phthalonitrile resin precursor (CA‐Ph), which contains free phenolic hydroxyl groups that result in ‘self‐curing’ at elevated temperatures to afford a thermostable polymer. Comparison of the performance of this CA‐Ph resin with that of a conventional petroleum‐based bisphenol A phthalonitrile resin (BPA‐Ph; containing 5 wt% of the curing agent 4,4′‐diaminodiphenylsulfone) revealed that CA‐Ph exhibits a lower melting point and curing temperature. Cured CA‐Ph resin retains 95% of its weight at 520 °C under a nitrogen atmosphere, which compares favorably with results obtained for BPA‐Ph resin that retains 95% of its weight at a lower temperature of 484 °C. Kinetic results indicated that the curing reactions of both CA‐Ph and BPA‐Ph systems follow an autocatalytic mechanism. These results suggest that catechin is a useful bio‐based feedstock for the preparation of self‐curing and thermally stable phthalonitrile resins for advanced technological applications. © 2017 Society of Chemical Industry

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“…Nevertheless, these methods were time consuming and destructive in the testing process. In order to detect the resin curing process rapidly, spectroscopic techniques like Fourier transform infrared spectroscopy (IR) and nuclear magnetic resonance (NMR) were applied. Chang et al investigated the curing process of epoxy and graphene composites materials, it monitored the process from the decrease in the intensity of characteristic bands of epoxide ring (915 cm −1 ) and the increase in the OH stretching band intensity (3,380 cm −1 ) by IR.…”

Section: Introductionmentioning

confidence: 99%

Nondestructive rapid and quantitative analysis for the curing process of silicone resin by near‐infrared spectra

Yang

Zhang

Yin

et al. 2020

J of Applied Polymer Sci

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Reactive group content was a key parameter in polymer curing process. However, the conventional methods to measure the curing were destructive and time consuming. In this article, near‐infrared spectra technology had been applied for reactive group analysis of the photothermal curing silicone to achieve rapid nondestructive and quantitative detection. The calibration model was developed about epoxy value and CC double bond value, with determination coefficient (R2) of 0.9631 and 0.9689. Root mean square error of prediction were 0.0179 and 0.0143 by partial least square regression. The optimized calibration model was used to predict the content of epoxy value and CC double bond value in the photothermal curing process, it proved that the silicone resin cured under UV‐radiation and heat. This novel method provided a promising approach to analysis the curing mechanism and quality parameters of resin.

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A high temperature polymer of phthalonitrile‐substituted phosphazene with low melting point and good thermal stability

Cited by 30 publications

References 49 publications

Branched phenyl‐s‐triazine moieties to enhance thermal properties of phthalonitrile thermosets

Branched phenyl‐s‐triazine moieties to enhance thermal properties of phthalonitrile thermosets

A novel bio‐based phthalonitrile resin derived from catechin: synthesis and comparison of curing behavior with petroleum‐based counterpart

Nondestructive rapid and quantitative analysis for the curing process of silicone resin by near‐infrared spectra

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