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

Abstract: 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… Show more

“…The higher disintegration occurred after 20 days, which agrees with the results obtained by Arrieta et al and Ghorpade et al, which mention that PLA presents more significant degradation after 2 weeks of composting 44,45 . This behavior is because, during the first days of composting, the microorganisms adapt to the environment, and the high molecular weight PLA chains begin to hydrolyze to form lower molecular weight chains to be later metabolized by the microorganisms 30,46 . The samples subjected to weathering (PLAW and PLAEW) showed faster disintegration with each reprocessing cycle; combined hydrolysis and UV light start the degradation of PLA, causing shorter polymeric chains that microorganisms can easily consume.…”

“…The initial carbonyl index for PLA was 3.43, and the values corresponding to the samples reprocessed by extrusion showed slight increases in the intensity of this signal which occurred by the oxidation reactions that induce the formation of carboxylic acids. The samples exposed to weathering and extrusion presented higher increases in carbonyl groups; this is due to photo‐oxidation, which occurs mainly by the Norrish II mechanism, which has as its final stage the formation of chains with carbonyl terminal groups, which causes an increase in this index 30 . Similar results are obtained with the PLAEJW samples.…”

“…The samples exposed to weathering and extrusion presented higher increases in carbonyl groups; this is due to photo-oxidation, which occurs mainly by the Norrish II mechanism, which has as its final stage the formation of chains with carbonyl terminal groups, which causes an increase in this index. 30 Similar results are obtained with the PLAEJW samples. The samples exposed to weathering without extrusion presented decreases in the carbonyl groups.…”

“…44,45 This behavior is because, during the first days of composting, the microorganisms adapt to the environment, and the high molecular weight PLA chains begin to hydrolyze to form lower molecular weight chains to be later metabolized by the microorganisms. 30,46 The samples subjected to weathering (PLAW and PLAEW) showed faster disintegration with each reprocessing cycle; combined hydrolysis and UV light start the degradation of PLA, causing shorter polymeric chains that microorganisms can easily consume. In this sense, the addition of Joncryl was a concern for the composting of PLA since it was expected that longer chains would be more difficult to disintegrate.…”

Mechanical recycling of PLA: Effect of weathering, extrusion cycles, and chain extender

“…The higher disintegration occurred after 20 days, which agrees with the results obtained by Arrieta et al and Ghorpade et al, which mention that PLA presents more significant degradation after 2 weeks of composting 44,45 . This behavior is because, during the first days of composting, the microorganisms adapt to the environment, and the high molecular weight PLA chains begin to hydrolyze to form lower molecular weight chains to be later metabolized by the microorganisms 30,46 . The samples subjected to weathering (PLAW and PLAEW) showed faster disintegration with each reprocessing cycle; combined hydrolysis and UV light start the degradation of PLA, causing shorter polymeric chains that microorganisms can easily consume.…”

“…The initial carbonyl index for PLA was 3.43, and the values corresponding to the samples reprocessed by extrusion showed slight increases in the intensity of this signal which occurred by the oxidation reactions that induce the formation of carboxylic acids. The samples exposed to weathering and extrusion presented higher increases in carbonyl groups; this is due to photo‐oxidation, which occurs mainly by the Norrish II mechanism, which has as its final stage the formation of chains with carbonyl terminal groups, which causes an increase in this index 30 . Similar results are obtained with the PLAEJW samples.…”

“…The samples exposed to weathering and extrusion presented higher increases in carbonyl groups; this is due to photo-oxidation, which occurs mainly by the Norrish II mechanism, which has as its final stage the formation of chains with carbonyl terminal groups, which causes an increase in this index. 30 Similar results are obtained with the PLAEJW samples. The samples exposed to weathering without extrusion presented decreases in the carbonyl groups.…”

“…44,45 This behavior is because, during the first days of composting, the microorganisms adapt to the environment, and the high molecular weight PLA chains begin to hydrolyze to form lower molecular weight chains to be later metabolized by the microorganisms. 30,46 The samples subjected to weathering (PLAW and PLAEW) showed faster disintegration with each reprocessing cycle; combined hydrolysis and UV light start the degradation of PLA, causing shorter polymeric chains that microorganisms can easily consume. In this sense, the addition of Joncryl was a concern for the composting of PLA since it was expected that longer chains would be more difficult to disintegrate.…”

Mechanical recycling of PLA: Effect of weathering, extrusion cycles, and chain extender

“…20,21 From the point of view of technical characteristics, PLA has high tensile strength, high elastic modulus, good transparency, biocompatibility, and good processability, generating potential for applications in packaging and the biomedical area. [22][23][24] Thus, PLA is considered a bioplastic with all the characteristics to replace traditional plastic. 25 However, the main drawback of PLA is its low impact strength, which limits its application in parts that require high impact.…”

On the Production of Poly(Lactic Acid) (PLA) Compounds with Metallic Stearates Based on Zinc, Magnesium and Cobalt. Investigation of Torque Rheometry and Thermal Properties

Reprocessing and Recycling of Poly(Lactic Acid): A Review