Abstract:This study aimed to develop cellulose-based polymer matrices as controlled release devices for plant-based insect repellents and attractants, with the aim of finding sustainable and environmentally friendly pest control methods for agricultural applications. Citronellol, terpineol and methyl salicylate were the selected active compounds for this study. Their compatibility with cellulose diacetate was predicted using Hansen Solubility Parameters, which predicted terpineol as the most compatible with cellulose d… Show more
“…4 show that the T g of the CD used in this study was about 220 °C. This T g is comparable to the T g values of around 190–226 °C which were obtained in previous studies for CD with degrees of substitution of between 2.45 and 2.50 [ 19 , 37 , 38 ]. Fig.…”
Enhancing the melt processability of cellulose is key to broadening its applications. This is done via derivatization of cellulose, and subsequent plasticization and/or blending with other biopolymers, such as polylactic acid (PLA) and polybutylene adipate terephthalate (PBAT). However, derivatization of cellulose tends to reduce its biodegradability. Moreover, traditional plasticizers are non-biodegradable. In this study, we report the influence of polyethylene glycol (PEG) plasticizer on the melt processibility and biodegradability of cellulose diacetate (CD) and its blends with PLA and PBAT. CD was first plasticized with PEG (PEG-200) at 35 wt%, and then blended with PLA and PBAT using a twin-screw extruder. Blends of the PEG plasticized CD with PLA at 40 wt% and with PBAT at 60 wt% were studied in detail. Dynamic mechanical analysis (DMA) showed that PEG reduced the glass transition of the CD from ca. 220 °C to less than 100 °C, indicating effective plasticization. Scanning electron microscopy revealed that the CD/PEG-PBAT blend had a smoother morphology implying some miscibility. The CD/PEG-PBAT blend at 60 wt% PBAT had an elongation-to-break of 734%, whereas the CD/PEG-PLA blend had a tensile strength of 20.6 MPa, comparable to that of the PEG plasticized CD. After a 108-day incubation period under simulated aerobic composting, the CD/PEG-PBAT blend at 60 wt% PBAT exhibited a biodegradation of 41%, whereas that of the CD/PEG-PLA at 40 wt% PLA was 107%. This study showed that melt processible, biodegradable CD blends can be synthesized through plasticization with PEG and blending with PBAT or PLA.
“…4 show that the T g of the CD used in this study was about 220 °C. This T g is comparable to the T g values of around 190–226 °C which were obtained in previous studies for CD with degrees of substitution of between 2.45 and 2.50 [ 19 , 37 , 38 ]. Fig.…”
Enhancing the melt processability of cellulose is key to broadening its applications. This is done via derivatization of cellulose, and subsequent plasticization and/or blending with other biopolymers, such as polylactic acid (PLA) and polybutylene adipate terephthalate (PBAT). However, derivatization of cellulose tends to reduce its biodegradability. Moreover, traditional plasticizers are non-biodegradable. In this study, we report the influence of polyethylene glycol (PEG) plasticizer on the melt processibility and biodegradability of cellulose diacetate (CD) and its blends with PLA and PBAT. CD was first plasticized with PEG (PEG-200) at 35 wt%, and then blended with PLA and PBAT using a twin-screw extruder. Blends of the PEG plasticized CD with PLA at 40 wt% and with PBAT at 60 wt% were studied in detail. Dynamic mechanical analysis (DMA) showed that PEG reduced the glass transition of the CD from ca. 220 °C to less than 100 °C, indicating effective plasticization. Scanning electron microscopy revealed that the CD/PEG-PBAT blend had a smoother morphology implying some miscibility. The CD/PEG-PBAT blend at 60 wt% PBAT had an elongation-to-break of 734%, whereas the CD/PEG-PLA blend had a tensile strength of 20.6 MPa, comparable to that of the PEG plasticized CD. After a 108-day incubation period under simulated aerobic composting, the CD/PEG-PBAT blend at 60 wt% PBAT exhibited a biodegradation of 41%, whereas that of the CD/PEG-PLA at 40 wt% PLA was 107%. This study showed that melt processible, biodegradable CD blends can be synthesized through plasticization with PEG and blending with PBAT or PLA.
“…Nanocomposites play an essential role in this research field. It improves materials properties by combining two or more different materials to produce a hybrid material [10][11][12]. Polymeric nanocomposites usually consist of inorganic solids like clays or oxides in nanometre scale and polymer mixtures.…”
The need for biodegradable composites has increased for many applications in recent years. Cellulose acetate (CA) and cellulose acetate butyrate (CAB) are relatively easy and cheap to fabricate, as well as relatively easy to decompose compared to other polymers. These materials are transparent and lightweight with low tensile properties. In this current study, the effect of Tapanuli clay addition on tensile and decomposition properties of CA and CA–CAB systems were investigated. Tapanuli organoclay was prepared by a cation exchange treatment using hexadecyltrimethylammonium bromide (HDTMA-Br) surfactant to Na-bentonite. Prior to the treatment, the Tapanuli clay was subjected to purification from organic and carbonate compounds and to balance the cations by homogenizing them into Na+. The basal spacing of Tapanuli clay increased from 1.52 nm up to 1.98 nm. CA and CA −5 wt% CAB composites were then synthesized using a solvent casting method. It was found that the addition of both 5 wt% CAB and 7 wt% organoclay in CA decreased the tensile strength and reduced the mass loss by 70%. After 45 days of the decomposition test, it was indicated that the presence of 5 wt% CAB in CA reduced the mass loss of the system by about 50%. These findings were con-firmed by the Scanning Electron Microscope (SEM) images which showed different patterns of as-synthesized and decomposed materials. In conclusion, the presence of 1 wt% Tapanuli organoclay slightly increased the decomposed mass of CA film and enhanced the tensile strength of CA-co-CAB.
“…Due to the high degradation resistance and extended time for the decomposition of non-biodegradable polymers, these polymers have significantly contributed to environmental problems. To alleviate these problems caused by non-biodegradable polymers, the use of biopolymer and biodegradable polymers is a viable alternative due to the renewability of their sources, availability, biodegradability, and eco-friendliness [ 4 , 5 , 6 ]. Biodegradable polymers have similar properties to conventional polymers; thus, these can replace non-biodegradable conventional polymers in many applications such as packaging, medical devices, drug capsules, personal hygiene products, and agricultural applications [ 2 ].…”
The extensive use of non-biodegradable plastic products has resulted in significant environmental problems caused by their accumulation in landfills and their proliferation into water bodies. Biodegradable polymers offer a potential solution to mitigate these issues through the utilization of renewable resources which are abundantly available and biodegradable, making them environmentally friendly. However, biodegradable polymers face challenges such as relatively low mechanical strength and thermal resistance, relatively inferior gas barrier properties, low processability, and economic viability. To overcome these limitations, researchers are investigating the incorporation of nanofillers, specifically bentonite clay, into biodegradable polymeric matrices. Bentonite clay is an aluminum phyllosilicate with interesting properties such as a high cation exchange capacity, a large surface area, and environmental compatibility. However, achieving complete dispersion of nanoclays in polymeric matrices remains a challenge due to these materials’ hydrophilic and hydrophobic nature. Several methods are employed to prepare polymer–clay nanocomposites, including solution casting, melt extrusion, spraying, inkjet printing, and electrospinning. Biodegradable polymeric nanocomposites are versatile and promising in various industrial applications such as electromagnetic shielding, energy storage, electronics, and flexible electronics. Additionally, combining bentonite clay with other fillers such as graphene can significantly reduce production costs compared to the exclusive use of carbon nanotubes or metallic fillers in the matrix. This work reviews the development of bentonite clay-based composites with biodegradable polymers for multifunctional applications. The composition, structure, preparation methods, and characterization techniques of these nanocomposites are discussed, along with the challenges and future directions in this field.
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