Water Resistance, Mechanical Properties and Water-Induced Shape Memory Properties of Poly(vinyl Alcohol) Materials Modified by Waste Polyester Depolymerization Monomer

Shen, Yue; He, Hui; Zhai, Hongyu; Li, Qunyang; Ye, Xun; Zhang, Cheng

doi:10.1021/acsapm.3c02880

ACS Appl. Polym. Mater.

2024

DOI: 10.1021/acsapm.3c02880

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Water Resistance, Mechanical Properties and Water-Induced Shape Memory Properties of Poly(vinyl Alcohol) Materials Modified by Waste Polyester Depolymerization Monomer

Yue Shen,

Hui He,

Hongyu Zhai

et al.

Abstract: Depolymerizing waste polyethylene terephthalate (PET) into monomers and subsequently processing and utilizing them is widely acknowledged as one of the most effective recycling methods for waste PET. The poor water stability of poly(vinyl alcohol) (PVA) necessitates modification to enhance its application scope. Thus, this study explores the use of recycled terephthalic acid (rTPA) obtained from waste PET depolymerization to modify PVA, aiming to improve its water resistance, functionalize it, and expand its p… Show more

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Cited by 2 publications

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Effect of silver nanoparticles modified by depolymerized monomer from waste PET on the thermo‐induced shape memory properties of PVA

Shen,

He,

Zhang

et al. 2024

Polymer Engineering & Sci

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Depolymerization of waste polyethylene terephthalate (PET) into monomers for high‐value reuse serves as an effective recycling strategy. Polyvinyl alcohol (PVA) is an important water‐soluble polymer, which can be improved by the addition of silver nanoparticles modified with depolymerized monomer terephthalic acid (rTPA) to further improve the shape memory performance of PVA. Silver nanoparticles are notably responsive to thermal changes due to their distinctive chemical and physical properties. Nonetheless, their tendency to aggregate and high surface energy present difficulties in achieving stable dispersions in aqueous environments. In this research, silver nitrate solution was reduced to prepare silver nanoparticles under the action of the reducing agent ascorbic acid. Modified silver nanoparticles p‐rTPA@Ag were prepared by co‐precipitation of the nanoparticles with rTPA. A mixture of PVA and p‐rTPA@Ag was prepared to form a composite PVA/p‐rTPA@Ag. Modified silver nanoparticles, p‐rTPA@Ag, exhibited enhanced dispersion in aqueous solution. The elongation at break of the composite rose markedly from 169.8% to 315.3%, an increase of 86.7%. Additionally, the shape recovery rate improved from 53.51% to 83.86%, reflecting a 56.7% enhancement.Highlights Silver nanoparticles were modified by depolymerized terephthalic acid (rTPA) Monomer rTPA improves the compatibility between PVA and Ag nanoparticles p‐rTPA@Ag enhances temperature sensitivity of PVA p‐rTPA@Ag enhances thermo‐induced shape memory properties of PVA

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Effect of silver nanoparticles modified by depolymerized monomer from waste PET on the thermo‐induced shape memory properties of PVA

Shen,

He,

Zhang

et al. 2024

Polymer Engineering & Sci

View full text Add to dashboard Cite

show abstract

High-Strength Thermally Activated Shape-Adaptive Plugging Hydrogels with Plastic Semicrystalline Metallosupramolecular Polymer Networks

Liu,

Ren,

Dong

et al. 2024

ACS Appl. Polym. Mater.

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Plugging materials are employed to repair holes or cracks in pipes, vessels, other equipment, or even formations. Traditional packing tape or sealant could seal only small cracks and leaks. Epoxy resins and polyurethane foams are appropriate for sealing relatively large apertures. However, their application is limited by a long curing time or low mechanical performance. Herein, we report thermally activated shape-adaptive plugging materials based on shape-memory hydrogels with high strength and deformation capacity. Owing to the stiff hydrophobic crystalline side segments in the hydrogel network, the shape-memory hydrogel showed high mechanical performances with a compressive strength of 17.57 MPa and toughness of 2760 kJ m −3 . Upon immersion in Fe 3+ solution, the integration of these two orthogonal supramolecular interactions bestows the hydrogel with high-strength mechanical properties and a distinctive dual-programmed shape-memory performance. Importantly, the excellent shape-memory properties can allow the hydrogel to exhibit a distinctive shape-adaptive plugging behavior. When activated, the flaky intelligent hydrogel expands into a granular shape, allowing them to adaptively match fracture apertures in the leakage zone within a range of 2 to 4 mm, which result in high plugging efficiency and high plugging strength. Therefore, this intelligent, adaptive plugging based on high-strength shape-memory hydrogels could be a prominent candidate for a generation of plugging materials that can be applied in the oil field, waste gas or oil pipeline repairs, and various other plugging scenarios.

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Water Resistance, Mechanical Properties and Water-Induced Shape Memory Properties of Poly(vinyl Alcohol) Materials Modified by Waste Polyester Depolymerization Monomer

Cited by 2 publications

References 45 publications

Effect of silver nanoparticles modified by depolymerized monomer from waste PET on the thermo‐induced shape memory properties of PVA

Effect of silver nanoparticles modified by depolymerized monomer from waste PET on the thermo‐induced shape memory properties of PVA

High-Strength Thermally Activated Shape-Adaptive Plugging Hydrogels with Plastic Semicrystalline Metallosupramolecular Polymer Networks

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