Study of the Degradation of a TPS/PCL/Fique Biocomposite Material in Soil, Compost, and Water

Mosquera Rodríguez, Fabián Steven; Quintero Vélez, Alejandro; Córdoba Urrutia, Estivinson; Ramírez-Malule, Howard; Mina Hernandez, Jose Herminsul

doi:10.3390/polym15193952

Cited by 5 publications

References 36 publications

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Recycling of biodegradable biobased polymer/agave fiber biocomposites

Pérez‐Fonseca,

Reynoso‐Llamas,

Robledo‐Ortíz

et al. 2024

Polymer Composites

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Biodegradable biobased polymers are a promising solution to reduce the dependence on conventional plastics and minimize their environmental impact. This work evaluated the recycling capacity of a biodegradable polymer (MaterBi) and its composite with agave fibers. The materials were reprocessed by several cycles using compression molding. Service life simulation was performed using accelerated weathering. Samples from each reprocessing cycle were characterized in terms of melt flow index (MFI), color, porosity, water absorption, compostability, and mechanical and thermal properties. The MFI of MaterBi increased with each cycle, going from 3.5 to 95 g/10 min for the first to sixth cycles and from 2 to 117 g/10 min for the first and fourth cycles for the biocomposite. Reprocessing produced chain scission and modified the thermal and mechanical properties. MaterBi exhibited competitive mechanical properties compared to conventional polymers, even after four reprocessing cycles (tensile, flexural, and impact strengths of 27, 55 MPa, and 30 J/m). Besides potential cost reductions, the agave fiber addition positively affected the tensile and flexural modulus, which remained after the fourth cycle in 1100 and 2300 MPa. The results confirmed that MaterBi and its biocomposites can be recycled for several cycles, extending their useful life before final biodegradation.Highlights MaterBi (MB) and its agave fiber biocomposites are suitable for reprocessing. MB tensile and flexural properties remained stable after four reprocessing cycles. Agave fibers make MB more prone to weathering, impacting its properties. MB and its biocomposites degrade in water and compost conditions.

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Recycling of biodegradable biobased polymer/agave fiber biocomposites

Pérez‐Fonseca,

Reynoso‐Llamas,

Robledo‐Ortíz

et al. 2024

Polymer Composites

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Tailored and sustainable bio-composite thanks to synergetic interactions of polycaprolactone (PCL) and guar gum derivative

Assimi,

Boutriouia,

Jalit

et al. 2024

J Polym Res

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Characterization of PBAT/TPS blends for plastic wrapping materials of pathological waste buried in soil environments

Mohd Nizam,

Tuan Sharif,

Wen Da

et al. 2024

Progress in Rubber, Plastics and Recycling Technology

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This study investigates the incorporation of thermoplastic starch (TPS) into polybutylene adipate terephthalate (PBAT) to create biodegradable plastic wraps for pathological waste burial in soil. TPS is added to PBAT to enhance biodegradability, as PBAT alone degrades slowly. The research examines the mechanical properties, biodegradation, morphology, and swelling behaviour of the blends. Key tests include xenon arc light exposure for accelerated aging, a formalin swelling test for permeability, and soil degradation analysis for weight loss. Results show that adding TPS significantly reduces tensile strength (65.53%) and elongation at break (93.35%), but the material still effectively serves its purpose as a wrapping for pathological waste. Morphological analysis reveals phase separation, and UV exposure further decreases tensile strength by 27.6%. The highest TPS composition (30TPS/70PBAT) shows the fastest mechanical degradation, indicating accelerated biodegradation. Despite minimal formalin absorption (16% within 1 day), the blends prevent formalin leaching, making them suitable for pathological waste containment.

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Study of the Degradation of a TPS/PCL/Fique Biocomposite Material in Soil, Compost, and Water

Cited by 5 publications

References 36 publications

Recycling of biodegradable biobased polymer/agave fiber biocomposites

Recycling of biodegradable biobased polymer/agave fiber biocomposites

Tailored and sustainable bio-composite thanks to synergetic interactions of polycaprolactone (PCL) and guar gum derivative

Characterization of PBAT/TPS blends for plastic wrapping materials of pathological waste buried in soil environments

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