Influence of the Degradation Medium on Water Uptake, Morphology, and Chemical Structure of Poly(Lactic Acid)-Sisal Bio-Composites

Moliner, Cristina; Finocchio, Elisabetta; Arato, Elisabetta; Ramis, Gianguido; Lagazzo, Alberto

doi:10.3390/ma13183974

Cited by 19 publications

(15 citation statements)

References 42 publications

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“…Poly(lactic acid) is one of the most readily degradable thermoplastic materials. The factors influencing on the mechanism and speed of PLA degradation under various environmental conditions were analyzed by many authors [8][9][10][11][12][13][14][15]. The main mechanism of PLA degradation is hydrolytic degradation or enzymatic degradation.…”

Section: Introductionmentioning

confidence: 99%

“…The most important factor influencing on PLA degradation carried out under natural and laboratory conditions are: the amount of D-lactide isomer in chain structure [13] and the degree of PLA crystallinity [14]. The rate of PLA hydrolysis is also strongly affected by the degradation conditions such as: temperature, humidity, and pH [9,11,15]. Moliner et al [11] reported for PLA samples after immersion during 30 days at room temperature in various aqueous solutions at different pH the limited hydrolysis of the ester bonds in PLA and the formation of few free alcoholic and carboxylic groups.…”

Section: Introductionmentioning

confidence: 99%

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Viscoelastic Properties of Epoxidized Natural Rubber/Poly(lactic acid) PLA/ENR Blends Containing Glycidyl-POSS and Trisilanolisooctyl-POSS as Functional Additives

2021

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The glycidyl-POSS (Polyhedral Oligomeric Silsesquioxanes, Polysilsesquioxane, POSS) (Gly-POSS) and trisilanolisooctyl-POSS (HO-POSS) were applied as functional additives influencing on the viscoelastic properties of the dynamic vulcanized PLA/ENR (poly(lactic acid)/epoxidized natural rubber) blends. The plasticizing effect of HO-POSS on PLA/ENR melt, leading to the decrease of complex viscosity at 160 °C, was observed. After the incorporation of Gly-POSS into PLA/ENR blends the complex viscosity increased confirming that the epoxy groups of Gly-POSS were able to react with the functional groups of ENR and the groups present at the end of PLA chains. The incorporation of Gly-POSS into 40:60 PLA/ENR blend provided significant enhancement of the storage shear modulus G’ at 30 °C. Furthermore, the glass transition temperatures Tg of ENR phase for PLA/ENR/Gly-POSS blends were shifted to higher values of temperature as compared with blends modified by HO-POSS. Strong reduction of the elongation at break Eb for 40:60 PLA/ENR/Gly-POSS blend indicated that Gly-POSS particles acted as multifunctional cross-links reducing elasticity of the material. The modification of 40:60 PLA/ENR blend by HO-POSS molecules led to lower values of composting coefficient KC indicating stronger deterioration of the mechanical properties that resulted from more intense degradation processes occurring during disposal in soil.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Viscoelastic Properties of Epoxidized Natural Rubber/Poly(lactic acid) PLA/ENR Blends Containing Glycidyl-POSS and Trisilanolisooctyl-POSS as Functional Additives

2021

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“…Figure 3 presents all characteristics absorption peaks of neat PLA, PLA10 and PLA20. IR reveals the presence of characteristic band absorptions: (i): 2996-2884 cm −1 , the asymmetric and symmetric stretching vibrations of CH 3 , (ii): 1747 cm −1 , an important characteristic band comes from the C O stretching, [10,35] (iii): 1475-1360 cm −1 , these other bends approximately come from the CH 3 and CH bending, (iv): 1270 cm −1 relative to the COC stretching vibration, (v): 1186-1031 cm −1 , the bands of the C O stretching of the CH(CH 3 ) OH end group of PLA [36,37] and (vi): 870-759 cm −1 , the C C stretching vibration and the C COO stretching band, respectively. [38] According to Figure 3, the incorporation of sisal fibers into PLA matrix produces some modifications in spectral regions.…”

Section: Ftir Spectra Analysismentioning

confidence: 99%

“…[8,9] Additional researches on PLA considered its use for applications in textiles, adhesive, agriculture products and packaging [5] due to its thermoplastic processing capacity and biodegradability properties under particular conditions. [10] However, its fragile character persists as it demonstrates a poor rigidity and low elongation at break, and its degradation rate remains slow. [1,2] Research has been carried out to resolve these defects by copolymerizing with other monomers, biocompatible plasticizers or nucleating agents.…”

Section: Introductionmentioning

confidence: 99%

Dielectric, vibrational and thermal properties of sisal fibers‐reinforced poly (lactic acid)

et al. 2020

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The dielectric spectroscopy (DS), the differential scanning calorimetry (DSC), the scanning electron microscope (SEM) and the Fourier transform infrared spectroscopy (FTIR) measurements were performed on a poly(lactic acid) matrix reinforced by sisal fibers with different weight fractions (10% and 20%). The obtained dielectric spectra of the neat PLA and the PLA/sisal biocomposites covered a wide frequency range (from 10 −1 to 10 6 Hz) and a temperature domain varying from 20 C to 140 C as it serves to investigate the polymer dynamics and the interfacial properties. The DSC analysis, the SEM micrographs and the FTIR spectra were executed to determine the characteristic temperatures, the degree of crystallinity and the interaction between poly(lactic acid) and sisal fibers. The DS showed different relaxations: the β relaxation, α process and the conduction phenomenon in the PLA matrix. Furthermore, the incorporation of sisal fiber generates additional relaxation processes known as the water polarization and the Maxwell-Wagner-Sillars (MWS) interfacial polarization. The PLA/sisal fiber interface properties were investigated through the calculation of the strength parameters Δε MWS as well as the activation energy using the Havriliak-Negami model. K E Y W O R D S bio-composites, interfacial polarization effect, sisal fibers, thermal properties 1 | INTRODUCTION The growing environmental and economic challenges have encouraged researchers and producers in the packaging industry to replace petrochemical-based polymers with biodegradable ones. [1] Among such bio-polymers, the poly(lactic acid) (PLA) elaborated from the polymerization of L-lactic acid is the most popular, as a result of its mechanical and thermal properties. [2] PLA is a semicrystalline, hydrophobic, low toxicity, biocompatible and biodegradable polymer. [3-5] However, the main obstacles to its broad commercialization and development are its brittle nature and slow crystallization. [6] This polymer has gained considerable interest in a variety of biomedical applications such as coating, absorbable sutures, stents, orthopedic plates and screws. [7] The PLA is also involved in other industrial sectors such as automobile, electronics and thermal insulation of buildings. [8,9] Additional researches on PLA considered its use for applications in textiles, adhesive, agriculture products and packaging [5] due to its thermoplastic processing capacity and biodegradability properties under particular conditions. [10] However, its fragile character persists as it demonstrates a poor rigidity and low elongation at break, and its degradation rate remains slow. [1,2] Research has been carried out to resolve these defects by copolymerizing

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“…Therefore, in various industries, such as packaging, automotive, construction, pharmaceutical, biotechnology, or horticulture, there is a growing demand for natural fibers. The rapid growing researches of biocomposites and their growing importance in the industry are reflected by the volume of publications or patents during the recent years [ 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 , 22 ].…”

Section: Introductionmentioning

confidence: 99%

Evaluation of the Mechanical and Biocidal Properties of Lapacho from Tabebuia Plant as a Biocomposite Material

et al. 2021

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The aim of this article is to discuss in detail the physicochemical properties of polylactide (PLA) reinforced by cortex fibers, which may cause bacterial mortality and increased biodegradation rates. PLA biocomposites containing cortex Lapacho fibers from Tabebuia (1–10 wt %) were prepared by extrusion and injection moulding processes. The effects of Lapacho on the mechanical and biocidal properties of the biocomposites were studied using tensile and impact tests, dynamic mechanical analysis (DMA), differential scanning calorimetry (DSC), thermogravimetry (TG), and the method of evaluating the antibacterial activity of antibacterial treated according to the standard ISO 22196:2011. It also presented the effects of Lapacho on the structural properties and biodegradation rates of biocomposites. This research study provides very important results complementing the current state of knowledge about the biocidal properties of Lapacho from Tabebuia plants and about cortex-reinforced biocomposites.

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Influence of the Degradation Medium on Water Uptake, Morphology, and Chemical Structure of Poly(Lactic Acid)-Sisal Bio-Composites

Cited by 19 publications

References 42 publications

Viscoelastic Properties of Epoxidized Natural Rubber/Poly(lactic acid) PLA/ENR Blends Containing Glycidyl-POSS and Trisilanolisooctyl-POSS as Functional Additives

Viscoelastic Properties of Epoxidized Natural Rubber/Poly(lactic acid) PLA/ENR Blends Containing Glycidyl-POSS and Trisilanolisooctyl-POSS as Functional Additives

Dielectric, vibrational and thermal properties of sisal fibers‐reinforced poly (lactic acid)

Evaluation of the Mechanical and Biocidal Properties of Lapacho from Tabebuia Plant as a Biocomposite Material

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