Phthalonitrile Containing Branched Cyanine: Structure, Curing, and Its Properties

Liu, Xiwei; Liu, Yumeng; Hu, Jianke; Wang, Yitian; Hu, Yanhong

doi:10.1021/acsapm.4c00746

ACS Appl. Polym. Mater.

2024

DOI: 10.1021/acsapm.4c00746

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Phthalonitrile Containing Branched Cyanine: Structure, Curing, and Its Properties

Xiwei Liu,

Yumeng Liu,

Jianke Hu

et al.

Abstract: In order to improve the reliability of phthalonitrile resins in extreme service environments, a high cyanodensity phthalonitrile monomer (BPN) containing branched cyano groups was synthesized from 3,4dihydroxybenzonitrile and 4-nitrophthalonitrile and characterized by 1 H NMR and FTIR. It was found that polymerized BPN (p-BPN) exhibited excellent thermal properties with a T d5 of 540 °C when tested in N 2 in the thermogravimetric analysis (TGA), as well as a glass transition temperature (T g ) of p-BPN1 exceed… Show more

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2024

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Cited by 2 publications

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The influence of phthalonitrile monomer containing oxazine ring on the properties of epoxy/amine system: Curing behavior and thermal stability

Chen,

Peng,

et al. 2024

J of Applied Polymer Sci

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Phthalonitrile monomer containing oxazine ring (BPS‐Ph) was synthesized using bisphenol‐S, aniline, paraformaldehyde, and 4‐nitrophthalonitrile via a two‐step method. The differential scanning calorimetry (DSC) data of the curing process of BPS‐Ph monomer indicates that the peak polymerization temperature of the cyan group is about 250°C and that confirms the promoting effect of oxazine ring on the curing reaction of phthalonitrile. The rheological data of E51/DDS containing BPS‐Ph indicates that the BPS‐Ph monomer also has promoting effect on the curing process. The activation energy was studied via the iso‐conversional method principle. The activation energy corresponding to the E51/DDS crosslinking reaction is 75.79 and 60.54 kJ mol−1, respectively, for pure E51/DDS and E51/DDS/BPS‐Ph. Moreover, the activation energy of the crosslinking of phthalhydrazine is 74.1 kJ mol−1 which is rather lower than that in pure BPS‐Ph, and that implies the synergistically catalytic effect of the oxazine ring and the amine. The addition of BPS‐Ph monomer significantly improves the thermal behaviors of the thermoset. The char yield in N2 atmosphere increased from 15.6% to 53.9% when adding 30% BPS‐Ph to the E51/DDS. Moreover, the peak weight loss temperature decreased from 407 to 385°C. The phase separation size of poly‐BPS‐Ph in E51/DDS is about tens to hundreds nanometers according to the atomic force microscopy (AFM) phase diagram. It is indicated that incorporation of phthalonitrile monomer containing oxazine ring into epoxy/amine system is an applicable and effective way to promote the thermal behavior of the thermoset.

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The influence of phthalonitrile monomer containing oxazine ring on the properties of epoxy/amine system: Curing behavior and thermal stability

Chen,

Peng,

et al. 2024

J of Applied Polymer Sci

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Construction of an In Situ-Generated Nanoscale Organic–Inorganic Hybrid System Using Hydrogen Bonding Interaction To Assist Thermal Properties of Resins

Wang,

Ding

et al. 2024

ACS Appl. Mater. Interfaces

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With the rapid development of science and technology, high-temperatureresistant resin systems are facing more severe challenges in extreme applications. To further improve the comprehensive thermal properties of phthalonitrile resins, an in situ generation of a high-temperature-resistant phthalonitrile resin achieving an organic−inorganic hybridization network is reported. A 3-aminophenol phthalonitrile containing −NH 2 is used as a material to hybridize with prepared calcium phosphate nano-oligomers (CPOs), and the hybrid precursor is named as CAPN. Notably, the hydrogen bonding plays a crucial role in the hybrid, as nanosize control of CPOs, and in the synthesis of CAPN. The presence of hydrogen bonding interaction is proved by Fourier transform infrared, Raman, 31 P solidstate nuclear magnetic resonance spectra, isothermal differential scanning calorimetric testing, and calculation of apparent activation energy (E a ). Based on organic−inorganic hybrid cross-linked networks formed by resins during the curing process, 50CAPN (the hybrid containing 50 wt % CPOs) has superior thermo-mechanical properties [glass transition temperature (T g ) > 580 °C] and thermal stability [5% pyrolysis temperature (T d5% (N 2 ) = 574 °C, T d5% (air) = 543 °C)] than the blending system 50HAPN [the mixture with 50 wt % nanohydroxyapatite (HAP)]. Additionally, under extreme high temperature and combustion conditions, it demonstrates that 50CAPN has more stable thermo-oxidative aging resistance and flame retardancy than 50HAPN. We believe that this organic−inorganic hybrid system of phthalonitrile formed based on hydrogen bonding will elevate the introduction of the inorganic phase into the organic phase for the preparation of high-temperature-resistant resin systems to a certain level.

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Phthalonitrile Containing Branched Cyanine: Structure, Curing, and Its Properties

Cited by 2 publications

References 34 publications

The influence of phthalonitrile monomer containing oxazine ring on the properties of epoxy/amine system: Curing behavior and thermal stability

The influence of phthalonitrile monomer containing oxazine ring on the properties of epoxy/amine system: Curing behavior and thermal stability

Construction of an In Situ-Generated Nanoscale Organic–Inorganic Hybrid System Using Hydrogen Bonding Interaction To Assist Thermal Properties of Resins

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