Impact of lithium chloride and <i>in‐situ</i> grafting on the performance of microcrystalline cellulose‐filled composites based on polyamide 6/high‐density polyethylene

Xu, Shihua; Fang, Yiqun; Yi, Shunmin; He, Jun; Zhai, Xianglin; Wang, Haigang; Wang, Qingwen

doi:10.1002/pc.25070

Cited by 2 publications

(1 citation statement)

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“…Xu et al. [ 29 ] reported a low melt point PA6/HDPE composite filled with microcrystalline cellulose by incorporating LiCl and found that the impact strength, flexural strength, and tensile strength of the composites with 1 wt% content of LiCl were improved simultaneously due to Li + ‐amide coordination. It can be speculated that introducing sacrificial bond into PA/rubber binary system may be a highly promising strategy to obtain outstanding toughness and strength at the same time.…”

Section: Introductionmentioning

confidence: 99%

Toward Largely Enhanced Toughness and Balanced Strength in PA1012/EPDM Blends via Synergistic Effect of Sacrificial Bonds and Network Structure

Sun

Wang

et al. 2021

Macro Materials & Eng

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Here, zinc‐neutralized ethylene propylene diene monomer (EPDM) ionomers with different neutralization levels are prepared through melt blending, and are then incorporated with polyamide 1012 (PA1012) to fabricate PA1012/EPDM ionomer blends. Interestingly, complex crosslinking networks are formed in the blends due to the construction of sacrificial bonds (Zn2+‐carboxyl, Zn2+‐amide). The as‐formed network structure and sacrificial bond endow the PA/EPDM blends with largely enhanced toughness (16 times higher than that of neat PA), as well as balanced strength and stiffness. Meanwhile, the rheological behaviors of PA1012/EPDM ionomer blends indicate their relative low melting viscosity, which can avoid the processing shortcomings of plastics toughened with rubber. Moreover, PA1012/EPDM ionomer blends show obvious gelation behavior, and a maximum notched Izod impact strength exhibited at the gel point, in which unique double network structure can be observed obviously, indicating that there is a corresponding correlation between the rheological and mechanical parameters. Furthermore, the supper‐toughening mechanism of PA1012/EPDM ionomer blends at gel point is explored, which origins from the large deformation and cavitation of rubber particles and the destruction of special double network morphologies. This study provides a novel and effective strategy to fabricate PA materials with outstanding toughness and excellent strength simultaneously.

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Section: Introductionmentioning

confidence: 99%