Fiber-matrix interface improvement via glycidyl methacrylate compatibilization for rotomolded poly(lactic acid)/agave fiber biocomposites

Robledo‐Ortíz, Jorge R.; González‐López, Martín Esteban; Campo, Alan S. Martín del; Peponi, Laura; González‐Núñez, Rubén; Rodrigue, Denis; Pérez‐Fonseca, Aida Alejandra

doi:10.1177/0021998320946821

Cited by 14 publications

(15 citation statements)

References 35 publications

(79 reference statements)

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“…This higher porosity allows easier access to humidity and oxygen, causing increments in the interfacial voids between fiber-matrix. 8,28 The color change of the materials is also presented in Figure 1 and Table 1. The most significant color parameter change corresponds to lightness (ΔL*); in other words, the samples became whiter with weathering.…”

Section: Physical Characterizationmentioning

confidence: 99%

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Influence of agro-industrial wastes over the abiotic and composting degradation of polylactic acid biocomposites

Campo

Robledo‐Ortíz

Arellano

et al. 2021

Journal of Composite Materials

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Combining polylactic acid (PLA) with waste fibers to produce reinforced biocomposites is of top interest to replace conventional polymers for environmentally friendlier materials. Natural fibers have a remarkable effect on the mechanical and thermal properties of the biocomposites. This reinforcing effect strongly depends on the chemical compositions of fibers, which will also influence the susceptibility of the biocomposites to abiotic and biotic degradation processes. This study evaluated the effect of agave and coir waste fibers over the abiotic and composting degradation of PLA-based biocomposites. Compression-molded PLA/agave and PLA/coir biocomposites using GMA-g-PLA as compatibilizer were subjected to accelerated weathering. Weathered and unweathered samples were further submitted to water absorption to analyze their hydrolytic degradation and composting for biotic degradation. Both fibers showed significant influence on biocomposites degradation. The role of the fibers in UV and hydrolytic degradation was positive for impact properties since the biocomposites were less affected than PLA. Water uptake was increased with fiber addition, while hydrolytic degradation was decreased. The weathering (abiotic degradation) accelerated the PLA biodegradation rate. In general, the results showed that adding both fibers to PLA could help its outdoor performance, maintaining the biodegradable characteristics of these materials.

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Section: Physical Characterizationmentioning

confidence: 99%

“…Agave and coir fibers are two of those wastes, with costs around $0.10 USD per kg, making them excellent alternatives to be used as reinforcements for PLA. 7,8 The Tequila process in Mexico produced around 563,000 tons of residual Agave tequilana Weber var. Azul fibers only in 2020.…”

Section: Introductionmentioning

confidence: 99%

Influence of agro-industrial wastes over the abiotic and composting degradation of polylactic acid biocomposites

Campo

Robledo‐Ortíz

Arellano

et al. 2021

Journal of Composite Materials

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“…Similar behavior was observed in flexural modulus results for both CM and RM samples. Even when it is well known that natural fibers possess high flexural modulus, the low wood/matrix compatibility, and the particle agglomeration can decrease this property in composites materials (Pérez-Fonseca et al 2015, Robledo-Ortíz et al 2021. The thermal annealing treatment did not significantly affect the tensile and flexural modulus since the biocomposites' values are similar to those of the untreated materials.…”

Section: Tensile and Flexural Propertiesmentioning

confidence: 91%

“…However, it is important to mention that even when it was found a significant decrease in flexural and tensile strength, the values are still competitive with those of polyethylene (flexural strength = 23 MPa, tensile strength 21 MPa), which is the most used polymer for rotomolding processes (95 % of the worldwide rotomolded parts) (Robledo-Ortíz et al 2021).…”

Section: Tensile and Flexural Propertiesmentioning

confidence: 99%

Crystallinity and impact strength improvement of wood-polylactic acid biocomposites produced by rotational and compression molding

Pérez‐Fonseca

Ramírez-Herrera

Talavera

et al. 2021

Maderas, Cienc. tecnol.

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“…At the same time, the important biodegradable nature of these materials could be positively or negatively affected. It is important to mention that the mechanical properties of these biodegradable polymers and their biocomposites are very competitive or even higher than those of petroleum‐based polymers 25 …”

Section: Introductionmentioning

confidence: 99%

Influence of the blending method over the thermal and mechanical properties of biodegradable polylactic acid/polyhydroxybutyrate blends and their wood biocomposites

Pérez‐Fonseca

Herrera-Carmona

González‐García

et al. 2021

Polymers for Advanced Techs

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This study focused on the effect of the processing method on the thermal, mechanical, and biodegradation properties of polylactic acid/polyhydroxybutyrate (PLA/PHB) blends and their wood biocomposites. The blending techniques were dry‐blending or twin‐screw extrusion, both followed by compression molding. PLA/PHB blends were prepared using 15 and 25% wt. of PHB and biocomposites with 20 and 30% wt. of wood particles. Moreover, a compatibilizer was used during the extrusion process to achieve better matrix‐fiber adhesion. The results showed that the crystallinity of PLA significantly increased with PHB and wood, especially after twin‐screw extrusion. The best results in tensile, flexural, and impact strength were obtained with the extruded and compatibilized PLA/PHB blends, with values higher than the neat biopolymers. The compatibilized biocomposite with 15% wt. PHB, and 20% wt. wood particles showed higher tensile, flexural, and impact properties than PLA. The biodegradation test showed that all samples were disintegrated (above 40%) after 40 days in compost medium, observing slight decreases in the biodegradation rate when PHB or wood particles were added. Even when the lower mechanical properties were obtained with the dry‐blending technique, they are still competitive for different applications, providing the possibility to produce blends and biocomposites, avoiding the extrusion process that requires more energy consumption and longer processing times.

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Fiber-matrix interface improvement via glycidyl methacrylate compatibilization for rotomolded poly(lactic acid)/agave fiber biocomposites

Cited by 14 publications

References 35 publications

Influence of agro-industrial wastes over the abiotic and composting degradation of polylactic acid biocomposites

Influence of agro-industrial wastes over the abiotic and composting degradation of polylactic acid biocomposites

Crystallinity and impact strength improvement of wood-polylactic acid biocomposites produced by rotational and compression molding

Influence of the blending method over the thermal and mechanical properties of biodegradable polylactic acid/polyhydroxybutyrate blends and their wood biocomposites

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