Biocompatible organic coating fabrication via polymer/clay nanocomposites: Evaluation of mechanical improvements

Kandemir, Ayse Cagil; Donmez, Fatma; Can, Hatice Kaplan

doi:10.1002/pc.27924

Cited by 2 publications

(1 citation statement)

References 52 publications

(133 reference statements)

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“…8 Therefore, numerous studies have been conducted aiming to enhance biopolymer films with various additives such as clay, cellulose, zinc oxide, silver nanoparticles, montmorillonite, titanium oxide, kaolinite, boehmite and an array of other materials known for their biodegradability and non-toxic properties. [9][10][11][12][13][14] This versatility provides various characteristics, such as smart/ intelligent or active features, to biopolymer-based materials, offering sustainable alternatives to regular plastics. [15][16][17] Seaweed's versatile applications as a biopolymer have garnered attention in various scientific studies particularly in food, packaging, and pharmaceutical applications.…”

Section: Introductionmentioning

confidence: 99%

The role of extracted Patchouli residue microparticle on the mechanical and microbial properties macroalgae biopolymer

Muhammad,

Abdullah,

Ahmad

et al. 2024

Polymer Composites

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Macroalgae is extensively being used to develop eco‐friendly biopolymer or biodegradable films, but have inferior mechanical strength. This study aims to enhance the mechanical properties of seaweed films by incorporating Patchouli microparticles (PMP) derived from dried Patchouli plants (DP‐PMP) and extracted residue (ER‐PMP) from Patchouli extraction process widely use in the perfume and cosmetic industry. The PMPs, were incorporated into films forming solution at varying concentrations (1%, 3%, 5%, and 7% wt/wt) respectively. Despite similar thermal properties, the inclusion of ER‐PMP resulted in an increasing ash residue content with an increase in concentration. The optimal tensile strength was achieved with a 3% PMP loading, while higher concentrations resulted in a decline in strength. Notably, the sample containing 1% PMP demonstrated superior elasticity. Moreover, with increasing concentrations of PMPs, all samples displayed elevated surface roughness and enhanced hydrophobicity. All samples display significant antimicrobial activity against E‐coli and Salmonella sp.; however, the sample incorporating ER‐PMP showed less effect. In summary, the study suggests that DP‐PMP and ER‐PMP can serve as effective fillers to enhance the mechanical properties of seaweed biofilms, with an optimal loading of 3%. Their antimicrobial activity renders them suitable biopolymers for active packaging in food applications and other purposes.Highlights Patchouli microparticle (PMP) enhance the properties of seaweed film. Film's surface morphology and hydrophobicity changed with increase in PMP. Introduction of either PMPs increase antimicrobial properties of the film. PMP from extracted residue (ER) provide lower antimicrobial activity. 3% DP‐PMP gave the optimum properties of the film for overall attributes.

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Section: Introductionmentioning

confidence: 99%

The role of extracted Patchouli residue microparticle on the mechanical and microbial properties macroalgae biopolymer

Muhammad,

Abdullah,

Ahmad

et al. 2024

Polymer Composites

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Comparative fracture surface analysis of adhesively bonded dissimilar lap joints: Nanosilica effect

Dizaji,

Khabaz‐Aghdam,

Kandemir

2024

Polymer Composites

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This research presents a comparative analysis of the fracture surfaces of adhesively bonded dissimilar single lap joints (DSLJs) and investigates the effect of nanosilica (NS) additives on their fracture behavior and performance. The study focuses on DSLJs composed of aluminum (Al), stainless steel (SS), copper (Cu), and carbon fiber reinforced polymer (CFRP) adherends bonded with an epoxy adhesive. The fracture surface of DSLJs is further analyzed by introducing two parameters: fractional total fracture area (aT) and the surface sensitivity of each adherend (aSurface). These parameters serve as benchmarks to predict the final load capacity of the adhesive joints. It is found that a decrease in and an increase in the sensitivity of the adherend with a lower Young's modulus lead to higher load capacity. Tensile tests revealed that incorporating NS up to a critical weight percentage of 0.6 wt% improves the proposed surface parameters and significantly contributes to higher levels of load capacity and absorbing greater amounts of energy to failure. Furthermore, numerical simulations offer insights into stress distribution and the mechanism of plastic deformation propagation, providing additional support for the experimental findings.Highlights NS up to 0.6 wt% enhances the mechanical properties of DSLJs. NS–epoxy interactions characterized through Fourier transform infrared and transmission electron microscopy analysis. Fracture surface patterns help to predict the final load capacity of DSLJs. Plastic propagation in epoxy verifies fracture surface pattern in DSLJs.

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Biocompatible organic coating fabrication via polymer/clay nanocomposites: Evaluation of mechanical improvements

Cited by 2 publications

References 52 publications

The role of extracted Patchouli residue microparticle on the mechanical and microbial properties macroalgae biopolymer

The role of extracted Patchouli residue microparticle on the mechanical and microbial properties macroalgae biopolymer

Comparative fracture surface analysis of adhesively bonded dissimilar lap joints: Nanosilica effect

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