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    Localized Surface Plasmon Resonance Property of Ag-Nanoparticles and Prospects as Imminent Multi-Functional Colorant

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    Cultivar difference characterization of kiwifruit wines on phenolic profiles, volatiles and antioxidant activity

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    Antioxidant activity and volatiles of kiwifruit wine with different flesh colors were investigated in this study. Green (Guichang and Xuxiang), red (Donghong and Hongyang), and yellow (Jinyan) kiwifruits were analyzed to determine their alcohol content, phenolic profiles, antioxidant activity, and aroma composition. The results showed that Hongyang and Donghong wines had higher antioxidant activity and content of antioxidant substances. Hongyang wine possessed the most abundance of polyphenolic compounds, chlorogenic acid and catechins were the main polyphenols of kiwi wines. The 101 aromatic components were detected, Xuxiang wine possessed 64 aromatic compounds, Donghong and Hongyang wines had the higher esters compositions, 79.87%, and 78.0% respectively. From PCA (Principal Component Analysis), the volatile substances of kiwi wine with the same flesh color were similar. Five kinds of kiwi wines shared 32 kinds of volatile compounds, these compounds may be the core volatiles in kiwi wine. Therefore, the color of kiwi flesh can impact wine flavor, with Hongyang and Donghong kiwis owning red flesh being the most suitable for producing kiwi wine which would be a new milestone to the wine manufactures

    Sustainable bamboo fiber reinforced polymeric composites for structural applications: A mini review of recent advances and future prospects

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    This article reviews the present status and prospects of sustainable bamboo fiber reinforced polymeric composites (BFRCs). Because of its rapid growth, renewability, and minimal environmental effect, bamboo has emerged as a viable contender in response to the increasing demand for eco-friendly materials across a variety of sectors. Bamboo is going to be a significant lignocellulosic material. Moreover, a summary of the production procedures, mechanical qualities, and uses of bamboo fiber reinforced composites also discussed. The problems and possibilities connected with the development of BFRCs which negatively influence their performance in a variety of industrial applications also addressed further

    Biopolymers-based microencapsulation technology for sustainable textiles development: A short review

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    Microencapsulation methods in product development may result in innovative products with improved stability, functionality, and active chemical release (s). Microcapsules may be made out of biopolymers instead of synthetic polymers because of their biodegradability, lower production costs, and greater accessibility. The potential of biopolymers-based microencapsulation technology in sustainable textiles is substantial despite this field only getting started. This short review explores the role of biopolymers such as chitosan, gelatin, alginate, and cellulose in microencapsulation-mediated sustainable textile technology. The long-term effects of using microencapsulation made from biopolymers are also discussed, with an eye toward sustainability

    Eco-friendly production of cellulosic fibers from Scots pine wood and sustainable nanosilver modification: A path toward sustainability

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    This study presents a novel approach for the production of cellulosic fibers from scots pine wood and their subsequent surface modification with greenly synthesized silver nanoparticles (AgNPs), leading to remarkable color effects and improved functionalities, particularly enhanced thermal stability. The size distribution of the scots pine fiber (SPF)materials was determined through sieve analysis, revealing a conversion of scots pine particles from 1.25 mm to 0.8 mm in size. The AgNPs were biosynthesized in situ on the wood fibers using the same fiber as a sustainable stabilizing and reducing agent. Scanning electron microscopy (SEM) was employed to investigate the morphologies of the control and AgNP-deposited samples, indicating a uniform distribution of nanosilver on the coated surfaces of the SPF material. The concentration of synthesized AgNPs on SPF was quantitatively measured using X-ray fluorescence (XRF) tests, ranging from 4149 ± 43 to 6329 ± 55 parts per million (PPM) depending on the AgNP concentration. The weight percentage of nanoparticles was determined by SEM-mediated energy-disruptive X-ray (EDX) analysis. Additional analyses, Fourier transform infrared spectroscopy (FTIR) test was also conducted. Thermal stability tests demonstrated an improving trend correlated with increasing nanosilver loading in the modified SPF materials. The coefficients of variation (R2) exhibited a significant relationship between nanosilver loading and most color parameters. Overall, this research presents a pioneering approach for the eco-friendly production of cellulosic fibers from scots pine wood and sustainable synthesis of AgNPs onto defibrated fibers, thus establishing a new benchmark for sustainable manufacturing processes
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