Toughness enhancement of polyamide 6,12 with intermolecular hydrogen bonding with <scp>3‐pentadecylphenol</scp>

Lu, Jing; Jalali, Amirjalal; Yao, Jianqi; Ma, Qian; Yin, Jiajie; Zhang, Rui‐Yan; Luo, Fa

doi:10.1002/app.52522

Cited by 8 publications

(3 citation statements)

References 41 publications

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“…74,75 Finally, it is important to note that, in this study, a significant amount of energy dissipation can be attributed to the decohesion of the matrix from highspecific-surface-area rubber nanofibrils at the interface when strong adhesion in the presence of the compatibilizer exists between the two components. 76,77 Notably, while the enhancement in elongation at break for compatibilized nanofibrillar composites is considerably more pronounced compared to noncompatibilized nanofibrillar and compatibilized spherical samples, it is noteworthy that the results for the latter two exhibit a close resemblance, albeit with a slightly greater improvement observed in the noncompatibilized samples. While neat HDPE exhibited a high elongation at break at room temperature, the in situ nanofibrillation process, coupled with the enhancement of the interface between the two components, resulted in a notable improvement in elongation at break under these conditions.…”

Section: Mechanical Propertiesmentioning

confidence: 93%

Enhancing Mechanical Performance of High-Density Polyethylene at Different Environmental Conditions with Outstanding Foamability through In-Situ Rubber Nanofibrillation: Exploring the Impact of Interface Modification

Kheradmandkeysomi,

Salehi,

Jalali

et al. 2024

ACS Appl. Mater. Interfaces

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In this study, we utilized in situ nanofibrillation of thermoplastic polyester ether elastomer (TPEE) within a high-density polyethylene (HDPE) matrix to enhance the rheological properties, foamability, and mechanical characteristics of the HDPE nanocomposite at both room and subzero temperatures. Due to the inherent polarity differences between these two components, TPEE is thermodynamically incompatible with the nonpolar HDPE. To address this compatibility issue, we employed a compatibilizer, styrene/ethylene-butylene/styrene copolymer-grafted maleic anhydride (SEBS-g-MA), to reduce the interfacial tension between the two blend components. In the initial step, we prepared a 10% masterbatch of HDPE/TPEE with and without the compatibilizer using a twin-screw extruder. Subsequently, we processed the 10% masterbatch further through spun bonding to create fiber-in-fiber composites. Scanning electron microscopy (SEM) analysis revealed a significant reduction in the spherical size of HDPE/TPEE particles following the inclusion of SEBS-g-MA, as well as a much smaller TPEE nanofiber size (approximately 60–70 nm for 5% TPEE). Moreover, extensional rheological testing revealed a notable enhancement in extensional rheological properties, with strain-hardening behavior being more pronounced in the compatibilized nanofibrillar composites compared to the noncompatibilized ones. SEM images of the foam structures depicted substantial improvement in the foamability of HDPE in terms of the cell size and density following the nanofibrillation process and the use of the compatibilizer. Ultimately, the in situ rubber fibrillation and enhancement of HDPE and TPEE interface using a compatibilizer led to increasing the HDPE ductility at room and subzero temperatures while maintaining its stiffness.

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Section: Mechanical Propertiesmentioning

confidence: 93%

Enhancing Mechanical Performance of High-Density Polyethylene at Different Environmental Conditions with Outstanding Foamability through In-Situ Rubber Nanofibrillation: Exploring the Impact of Interface Modification

Kheradmandkeysomi,

Salehi,

Jalali

et al. 2024

ACS Appl. Mater. Interfaces

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“…The PDP ratio was optimized since a higher impact strength for composites was achieved in our previous work. 17 Next, the ternary PA10,12/PDP/MWCNTs composites were prepared with various amounts of MWCNTs containing 0.8, 1.5, 2 and 2.5 wt%, respectively. Based on the MWCNT loading, all the ternary composites are denoted as PA/PDP/CNT+ X , in which X refers to the amount of CNT.…”

Section: Methodsmentioning

confidence: 99%

“…Wang et al 16 exploited H-bonds between nano-calcium whiskers and PA10,12 to effectively improve B30% the composite's tensile strength due to stress transfer enhancement. In our previous work, 17 we incorporated 30 wt% 3-pentadecylphenol (PDP) to tailor intermolecular H-bonds between PA6,12 and PDP, and the impact strength of the PA composite significantly enhanced to 17.5 kJ m À2 , whereas its tensile strength was dramatically decreased to 32 MPa.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics simulation of the 3–15alkyphenol compatibilizer in highly toughened and robust polyamide 10,12/MWCNT composites

Jin,

Jalali,

Zhai

et al. 2024

Phys. Chem. Chem. Phys.

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Toward the production of bioblends for the automotive sector: Reuse of recycled polyamide 6,6 to prepare super‐tough biopolyethylene

Barreto Luna,

Lama,

de Matos Costa

et al. 2024

J of Applied Polymer Sci

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Plastics reuse is essential for promoting a sustainable future, especially by mitigating environmental impacts. Recycled polyamide 66 (PA66r) was reused for the produce biopolyethylene (BioPE)‐based blends, aiming to obtain a super‐tough material. Initially, a premix of PA66r with maleic anhydride‐grafted ethylene–propylene–diene (EPDM‐MA) was obtained in an internal mixer. Subsequently, the BioPE/PA66r and BioPE/(PA66r/EPDM‐MA) blends were processed in a twin‐screw extruder and injection molded. The rheological, mechanical, thermal, thermomechanical, structural, and morphological properties were investigated. Torque rheometry indicated an increase in the viscosity of the BioPE/(PA66r/EPDM‐MA) blends compared to BioPE/PA66r, which was confirmed by a reduction in the melt flow index (MFI). EPDM‐MA promoted greater stability in BioPE/(PA66r/EPDM‐MA) blends during processing, reducing the degradation rate and molecular weight loss. The BioPE/(PA66r/EPDM‐MA) blend with the 70/(15/15)% composition exhibited super‐tough behavior, with 822.4 J/m impact strength and 233% elongation at break. Scanning electron microscopy indicated a fracture with high plastic deformation, elongated fibrils, and refined particles (0.64 μm), confirming the high toughness. Apparently, a core‐shell morphology was formed, which favored maintaining tensile strength, Shore D hardness, and heat deflection temperature comparable to pure BioPE. The results indicate potential for application in the automotive industry, contributing to reintroducing recycled material into the production chain.

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Toughness enhancement of polyamide 6,12 with intermolecular hydrogen bonding with 3‐pentadecylphenol

Cited by 8 publications

References 41 publications

Enhancing Mechanical Performance of High-Density Polyethylene at Different Environmental Conditions with Outstanding Foamability through In-Situ Rubber Nanofibrillation: Exploring the Impact of Interface Modification

Enhancing Mechanical Performance of High-Density Polyethylene at Different Environmental Conditions with Outstanding Foamability through In-Situ Rubber Nanofibrillation: Exploring the Impact of Interface Modification

Molecular dynamics simulation of the 3–15alkyphenol compatibilizer in highly toughened and robust polyamide 10,12/MWCNT composites

Toward the production of bioblends for the automotive sector: Reuse of recycled polyamide 6,6 to prepare super‐tough biopolyethylene

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