Hyperbranched Phosphorus-Containing Benzoxazine for Epoxy Modification: Flame Retardant and Toughening Agent

Jin, Dandan; Dai, Jinyue; Zhang, Liyue; Chen, Qing; Liu, Xiaoqing

doi:10.1021/acs.iecr.3c00418

Cited by 8 publications

(5 citation statements)

References 61 publications

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“…In addition, the av-EHC and av-CO 2 Y decreased from 22.7 MJ/m 2 and 1.5 kg/kg for EP to 21.3 MJ/m 2 and 1.1 kg/kg for FREP20, which indicated the gaseous phase flame-retardant effect of IA-EHBP. , As predicted, the residue char (RC) of FREPs steadily increased when increasing the concentration of IA-EHBP, and the RC of FREP20 (13.8 wt %) was much higher than that of EP (1.2 wt %). The addition of IA-EHBP facilitated the production of a physical barrier to prevent the underlying materials from transferring heat or mass, which was in accordance with the TGA results. , Moreover, the average mass loss rate (AMLR) of FREPs was significantly reduced when compared with those of EP, indicating that IA-EHBP effectively enhanced the charring of FREPs. Compared with previously reported works about flame-retardant materials, − IA-EHBP exhibited the superiority of simultaneous improvement in flame retardancy and toughness of FREPs.…”

Section: Resultssupporting

confidence: 83%

“…The addition of IA-EHBP facilitated the production of a physical barrier to prevent the underlying materials from transferring heat or mass, which was in accordance with the TGA results. 61,62 Moreover, the average mass loss rate (AMLR) of FREPs was significantly reduced when compared with those of EP, indicating that IA-EHBP effectively enhanced the charring of FREPs. Compared with previously reported works about flame-retardant materials, 49−59 IA-EHBP exhibited the superi-ority of simultaneous improvement in flame retardancy and toughness of FREPs.…”

Section: Flame Retardancy and Flame-retardant Mechanism Of Frepsmentioning

confidence: 99%

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Closed-Loop Recycling of Tough and Flame-Retardant Epoxy Resins

Fang¹,

Zhang

Wu³

et al. 2023

Macromolecules

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Large-scale applications of flame-retardant epoxy resins have caused sustainability concerns on the use of renewable resources and end-of-life wastes. New strategies are required to address chemical recycling of fire-safe epoxy resins. Here, we demonstrated recyclable flame-retardant epoxy resins (FREPs) using itaconic acid-derived hyperbranched epoxy resin (IA-EHBP) and (1,3,5-hexahydro-s-triazine-1,3,5-triyl) benzyl mercaptan (HT-BM). The unique structure enabled a closed-loop chemical recyclable network that can be degraded into monomers with up to 86% yield of recovered monomers. The hyperbranched topological structure of IA-EHBP also contributed to a significant improvement in the strength and toughness of the FREPs. By using positron annihilation lifetime spectroscopy, the effects of free-volume hole size and relative fractional free-volume on the mechanical performance and dynamic mechanical properties of FREPs were studied, and the function relations were therefore established based on the Williams–Landel–Ferry equation. The incorporation of IA-EHBP effectively promoted the formation of char residue and produced phosphorus- and sulfur-containing free radicals to prevent the generation of combustible volatiles, thus enhancing the flame retardancy. The FREPs can be recycled and reused multiple times without loss of performance. The method reported here provides a facile and closed-loop approach for high-efficiency chemical recycling and reuse of end-of-life flame-retardant materials.

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Section: Resultssupporting

confidence: 83%

Section: Flame Retardancy and Flame-retardant Mechanism Of Frepsmentioning

confidence: 99%

Closed-Loop Recycling of Tough and Flame-Retardant Epoxy Resins

Fang¹,

Zhang

Wu³

et al. 2023

Macromolecules

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“…Besides, the chemical compositions of the char residues were further identified by XPS, as shown in Figures c–f and S9b-c. As shown in Figures c and S9b, except for C, N, and O elements, two additional peaks at 133.8 and 191.2 eV attributed to P 2s and P 2p were detected in the char residue for F-SF/F-EP, which explained the important role of P element in the condensed phase. , Meanwhile, in the fine spectrum of F-SF/F-EP, the split peaks at 285.9 eV in C 1s (Figure d), 532.4 eV in O 1s (Figure e), and 133.6 eV in P 2p (Figure f) indicated the presence of P–O–C, and the signals at 288.8 eV in C 1s and 399.6 eV in N 1s (Figure S9c) were assigned to the formation of CN, contributing to the yield of a high-quality char layer . Compared with the results for SF/EP (Figure S10), which displayed a decreased relative content of unsaturated carbon and the absence of P–O–C signal, revealing the important role of PA, HGB, and DGEBDB in promoting the condensed phase.…”

Section: Resultsmentioning

confidence: 84%

Water-Soluble Biobased Modifier Toward Epoxy/Cellulose Fabric Composite with Simultaneous Enhancement of Flame Retardancy and Interface Adhesion

Zhang,

Liu,

Liu

et al. 2024

ACS Appl. Polym. Mater.

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Natural plant fibers, as green and lightweight alternatives to traditional fibers in fabricating green composites, have attracted much interest in recent years. However, their hydrophilic and flammable natures severely limit the interfacial adhesion and flame resistance of the composite, and the synchronous improvement of both remains a considerable challenge. Herein, a combined modifier consisting of a watersoluble benzoxazine (HGB) with high carbonization and phytic acid (PA) containing phosphorus elements and acid groups was devised to treat regenerated cellulose fabric (SF). The treated fabric (F-SF) not only could realize self-extinguishing from the fire, which helps to avoid the wick effects, but also exhibited an optimized interfacial property of the composites. After being combined with an intrinsic flame-retardant epoxy resin (F-EP), the composite material (F-SF/F-EP) achieved a V-0 rating in the UL-94 test and an excellent limiting oxygen index (LOI) value of 33.8% due to the flame-retardant effect in both the gaseous and condensed phases. Simultaneously, benefiting from the improved interfacial compatibility, both the tensile modulus and impact strength were enhanced from 9.82 GPa and 6.58 MPa to 11.29 GPa and 7.21 MPa, respectively, compared with untreated SF/EP composite, especially the interlaminar shear strength (ILSS) dramatically increased by 21.7%. This work provided an integrated strategy for synchronously enhancing interfacial compatibility and the fire-proof performance of plant fiber-reinforced composites.

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“…Thermosetting epoxy resins (EPs) and their composites are widely used in various fields, such as aerospace, automotive, and construction, owing to their good strength, heat resistance, and dimensional stability. – Their superior performances are attributed to the presence of covalently cross-linked networks. – However, the structure of the cross-linked network is hard to control, leading to difficulties in regulating properties, such as strength, toughness, corrosion resistance, and thermal properties, and overcoming the inherent strength–toughness trade-off. , Generally, the highly rigid cross-linked structures make it difficult for thermosetting resins to dissipate internal stress caused by various applied loads, allowing the formation and evolution of cracks during use and finally resulting in the permanent failure of materials. , Considering the nonrecyclability of thermosetting materials, this problem shortens their service life and is not conducive to the safe use and sustainable development of EPs . Therefore, constructing and regulating cross-linked networks that couple hardness with softness to achieve controllable properties and overcome the trade-off effect between strength and toughness are the biggest difficulties faced in the development of EPs.…”

Section: Introductionmentioning

confidence: 99%

Novel Multifunction Epoxy Thermoset Designed by Manipulating the Silicon-Oxidation Flexible-Rigid Network Topology: Toughening, Strengthening, and Acid/Alkali Resistance

Xu,

Zhang,

Wang

et al. 2023

Ind. Eng. Chem. Res.

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Hyperbranched Phosphorus-Containing Benzoxazine for Epoxy Modification: Flame Retardant and Toughening Agent

Cited by 8 publications

References 61 publications

Closed-Loop Recycling of Tough and Flame-Retardant Epoxy Resins

Closed-Loop Recycling of Tough and Flame-Retardant Epoxy Resins

Water-Soluble Biobased Modifier Toward Epoxy/Cellulose Fabric Composite with Simultaneous Enhancement of Flame Retardancy and Interface Adhesion

Novel Multifunction Epoxy Thermoset Designed by Manipulating the Silicon-Oxidation Flexible-Rigid Network Topology: Toughening, Strengthening, and Acid/Alkali Resistance

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